Genomic changes of Chagas disease vector, South America.We analyzed the main karyologic changes that have occurred during the dispersal of Triatoma infestans Triatoma infestans is a blood-sucking bug (like all the members of its subfamily Triatominae) and the most important vector of Chagas disease. It is widespread in the Southern Cone countries of South America; that is, in Bolivia, Argentina, Uruguay, Paraguay, Chile, Brazil , the main vector of Chagas disease Cha·gas disease or Cha·gas-Cruz disease n. See South American trypanosomiasis. . We identified two allopatric al·lo·pat·ric adj. Ecology Occurring in separate, nonoverlapping geographic areas. Often used of populations of related organisms unable to crossbreed because of geographic separation. groups, named Andean and non-Andean. The Andean specimens present C-heterochromatic blocks in most of their 22 chromosomes, whereas non-Andean specimens have only 4-7 autosomes with C-banding. These heterochromatin heterochromatin /het·ero·chro·ma·tin/ (-kro´mah-tin) that state of chromatin in which it is dark-staining, genetically inactive, and tightly coiled. het·er·o·chro·ma·tin n. differences are the likely cause of a striking DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. content variation (approximately 30%) between Andean and non-Andean insects. Our study, together with previous historical and genetic data, suggests that T. infestans was originally a sylvatic sylvatic /syl·vat·ic/ (sil-vat´ik) sylvan; pertaining to, located in, or living in the woods. sylvatic found in the woods; occurring in animals of the forest. species, with large quantities of DNA and heterochromatin, inhabiting the Andean region Andean region may refer to:
********** American trypanosomiasis American trypanosomiasis a disease of humans caused by Trypanosoma cruzi in which many animal species can act as carriers. The disease in dogs includes anemia, debility and splenomegaly; in cats there are posterior paralysis and convulsions. or Chagas disease is well recognized as the most serious human parasitic disease of the Americas in terms of its social and economic impact (1). This disease is caused by the flagellate flagellate /flag·el·late/ (flaj´e-lat) 1. any microorganism having flagella. 2. mastigote. 3. having flagella. 4. to practice flagellation. protozoan protozoan (prō'təzō`ən), informal term for the unicellular heterotrophs of the kingdom Protista. Protozoans comprise a large, diverse assortment of microscopic or near-microscopic organisms that live as single cells or in simple Trypanosoma cruzi Trypanosoma cru·zi n. A protozoan that is the causative agent of South American trypanosomiasis. , and it is transmitted by bloodsucking blood·suck·er n. 1. An animal, such as a leech, that sucks blood. 2. An extortionist or a blackmailer. 3. A person who is intrusively or overly dependent upon another; a parasite. insects of the subfamily subfamily /sub·fam·i·ly/ (sub´fam-i-le) a taxonomic division between a family and a tribe. sub·fam·i·ly n. A taxonomic category ranking between a family and a genus. Triatominae (Hemiptera, Reduviidae). There is no vaccine against T. cruzi; therefore, disease control relies on eliminating domestic vector populations by spraying infested in·fest tr.v. in·fest·ed, in·fest·ing, in·fests 1. To inhabit or overrun in numbers or quantities large enough to be harmful, threatening, or obnoxious: houses with residual insecticides. The epidemiologic importance of Chagas disease vectors largely depends on the vectors' spreading ability and adaptation to domestic habitats. Therefore, studies on the changes that have taken place in such domestication domestication Process of hereditary reorganization of wild animals and plants into forms more accommodating to the interests of people. In its strictest sense, it refers to the initial stage of human mastery of wild animals and plants. and geographic expansion may contribute to understanding the basic process by which some species of Triatominae invade new habitats and colonize col·o·nize v. col·o·nized, col·o·niz·ing, col·o·niz·es v.tr. 1. To form or establish a colony or colonies in. 2. To migrate to and settle in; occupy as a colony. 3. human habitations. These analyses are fundamental in the design of control campaigns because their results will help determine the most appropiate strategy for insecticide application. Knowledge of the genetic structure of insect populations (including the evaluation of gene flow between domestic and sylvatic populations), as well as their domestication and spreading capabilities, are essential tools for effective vector control (2). Triatoma infestans represents the best example of spreading and adaptation to domicilies observed in a triatomine species. This species is the main and widespread vector in South America, responsible for about half of the 12 million cases of Chagas disease reported worldwide. Although its distribution is now being substantially reduced by large-scale control interventions within the Southern Cone Initiative, launched in 1991 by six South American countries (1), its distribution in the mid-1980s was very wide, including vast regions of Argentina The provinces of Argentina are often grouped into six geographical regions. From North to South and West to East, these are:
One important approach used to establish genetic variation in T. infestans is cytogenetie analysis. The diploid diploid /dip·loid/ (dip´loid) 1. having two sets of chromosomes, as normally found in the somatic cells; in humans, the diploid number is 46. 2. an individual or cell having two full sets of homologous chromosomes. chromosome number of Z infestans is 22, including 10 pairs of autosomes and 1 pair of sex chromosomes (XY in males, XX in females) (8). The three large autosomal Autosomal Relating to any chromosome besides the X and Y sex chromosomes. Human cells contain 22 pairs of autosomes and one pair of sex chromosomes. Mentioned in: Ataxia-Telangiectasia, Cutis Laxa, Hemochromatosis pairs and the Y chromosome Y chromosome, n a sex chromosome that in humans and many other species is present only in the male, appearing singly in the normal male. It is carried as a sex determinant by one half of the male gametes. None of the female gametes contain a Y chromosome. present C-heterochromatic blocks (9). Based on a great variation in the quantity and position of these C-heterochromatic regions, an extensive polymorphism polymorphism, of minerals, property of crystallizing in two or more distinct forms. Calcium carbonate is dimorphous (two forms), crystallizing as calcite or aragonite. Titanium dioxide is trimorphous; its three forms are brookite, anatase (or octahedrite), and rutile. in natural populations from Uruguay has been described (10). This variation in the three large autosomal pairs was also described in laboratory-reared specimens from Brazil, Paraguay, Argentina, and Chile (11,12). We present an extensive analysis, including specimens from several countries (Figure 1). Using flow cytometry flow cytometry (flōˑ sī·t  ˑ·m for DNA quantification and
C-banding technique, we have determined the karyologic changes that have
occurred during the dispersal of T. infestans. This analysis has allowed
us to identify two very different chromosomal groups and to discuss the
role of heterochromatin and genome size variation in the karyologic
evolution of T. infestans.[FIGURE 1 OMITTED] Materials and Methods Material Analyzed A total of 209 T. infestans specimens from natural populations were examined by C-banding (Tables 1 and 2, Figure 1). Currently, several of these populations, particularly from Uruguay and Brazil, have disappeared as a result of intensive control interventions. Five male specimens of the experimental progeny obtained by crossing insects from Brazil and Bolivia (Cochabamba Valley) were also examined. Flow cytometric analysis of DNA content was performed in 42 male insects. Student t test was used for statistical analysis of the results obtained by C-banding and flow cytometry; p < 0.001 was considered significant. Chromosome Preparations and Banding Procedures Gonads (testes testes or testicles Male reproductive organs (see reproductive system). Humans have two oval-shaped testes 1.5–2 in. (4–5 cm) long that produce sperm and androgens (mainly testosterone), contained in a sac (scrotum) behind the penis. and ovaries Ovaries The female sex organs that make eggs and female hormones. Mentioned in: Choriocarcinoma ovaries (ō´v ) from adult insects (occasionally fifth-stage nymphs) were removed, fixed in ethano--acetic acid (3:1), and stored at -20[degrees]C. C-banding treatment was carried out on air-dried squash, as previously described (13). The C-banding pattern for each specimen was determined by analyzing at least 10 cells. In males, both mitotic mitotic pertaining to mitosis. mitotic activity degree to which a cell population is proliferating; used as an index of tumor aggression. (spermatogonial prometaphase) and meiotic meiotic pertaining to meiosis. (metaphase metaphase /meta·phase/ (met´ah-faz) the second stage of cell division (mitosis or meiosis), in which the chromosomes, each consisting of two chromatids, are arranged in the equatorial plane of the spindle prior to separation. I or II) plates were observed. For females, only oogonial prometaphases were studied because no meiotic stages can be detected. The identification of each chromosomal pair was based on size differences and on the analysis of the meiotic configurations. Each pattern can be assigned to the corresponding chromosomal pair only when C-heterochromatin is present in three or four autosomal pairs. To describe the different C-banding patterns, three autosomal morphs, denoted A, B, and C, were recognized on the basis of previous reports (10,12) (Figure 2): A morph (a subterminal sub·ter·mi·nal adj. Located or occurring near an end. Adj. 1. subterminal - near but not precisely at an end; "a subterminal band of color on the tail feathers" C-heterochromatic block is present at one chromosomal end; the other end is euchromatic or has a very small C-band); B morph (C-heterochromatic blocks are clearly present at both chromosomal ends); and C morph (the chromosome is totally euchromatic or has a very small C-band). We estimated the relative length of the C-heterochromatin in the total length of the autosomal complement. At least three specimens from each population were analyzed. For each specimen, three to five photographs of the gonial metaphase plate metaphase plate n. An imaginary plane perpendicular to the spindle fibers of a dividing cell, along which chromosomes align during metaphase. were digitized and quantified by means of appropriate software (IPP (Internet Printing Protocol) A protocol for printing and managing print jobs over the Internet using HTTP. Initially conceived by Novell, Xerox and others, the IETF made it a standard in 2000 that includes authentication and encryption. See printing protocol and LPD. plus, Media Cybernetics cybernetics [Gr.,=steersman], term coined by American mathematician Norbert Wiener to refer to the general analysis of control systems and communication systems in living organisms and machines. , Carlsbad, CA). Measuring Genome Size by Flow Cytometry To establish the haploid haploid /hap·loid/ (hap´loid) 1. having half the number of chromosomes characteristically found in the somatic (diploid) cells of an organism; typical of the gametes of a species whose union restores the diploid number. genome size, we used flow cytometry to measure nuclear DNA content in gonad gonad /go·nad/ (go´nad) a gamete-producing gland; an ovary or testis.gonad´algonad´ial indifferent gonad the sexually undifferentiated gonad of the early embryo. cells from 42 male insects (Table 3) previously fixed in ethanolacetic acid (3:1). Gonads from fixed insects were excised and deposited on excavated glass slides. A few drops of hypotonic hypotonic /hy·po·ton·ic/ (-ton´ik) 1. denoting decreased tone or tension. 2. denoting a solution having less osmotic pressure than one with which it is compared. DNA-staining buffer (HDSB HDSB Halton District School Board (Ontario, Canada) HDSB Heavy Dry Support Bridge ), containing 0.1% trisodium citrate, 0.1% Triton X-100, 100 [micro]g/mL RNAase A, and 50 [micro]g/mL propidium iodide) were added to cover the tissue. Gonads were then minced by using scalpel blades until homogeneous slurries were obtained. These were transferred with a Pasteur pipette to 5-mL polypropylene tubes, with the glass slides washed with additional HDSB to obtain a final volume of 2 mL. The suspensions were then incubated for 30 min at 37[degrees]C in the dark with occasional vortexing of the tubes. Immediately before flow cytometric analysis, suspensions were filtered through 60-[micro]m nylon mesh. To evaluate absolute DNA contents, we used as reference the Normal DNA Index (Coulter Cytometry, PN 6699500). This reagent consists of normal human lymphocytes Lymphocytes Small white blood cells that bear the major responsibility for carrying out the activities of the immune system; they number about 1 trillion. fixed in ethanol: acetic acid acetic acid (əsē`tĭk), CH3CO2H, colorless liquid that has a characteristic pungent odor, boils at 118°C;, and is miscible with water in all proportions; it is a weak organic carboxylic acid (see carboxyl group). and is a standard for the human lymphocyte lymphocyte: see blood; immunity. lymphocyte Type of leukocyte fundamental to the immune system, regulating and participating in acquired immunity. Each has receptor molecules on its surface that bind to a specific antigen. genome size (2 C = 6.436 pg). All measurements were performed on an EPICS XL-MCL flow cytometer (Coulter Electronics, Hialeah, FL) with an air-cooled argon-ion laser tuned at 488 nm and 15 mW. Propidium fluorescence (FL3), proportional to DNA content, was collected through a 650-nm DL dichroic filter plus a 625-nm BP band-pass filter. Forward and side scatter signals were used for morphologic assessment of the samples. Cell aggregates and coincident cells were excluded by analysis of the relationship between FL3 integral and peak signals. DNA content in single cells was determined from FL3 linear histograms. The absolute DNA amount was calculated from the ratio of the mean channel of the insect haploid GO peak to the mean channel of the human lymphocyte diploid GO peak. To standardize the measurements, the flow cytometer was calibrated cal·i·brate tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates 1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): every day with standard FlowSet fluorescent microspheres (Coulter Cytometry), and replicate samples of Normal DNA Index were run with every batch of insect gonad cells. Results All Z infestans specimens had the same diploid chromosome number (2n = 22), constituted by 20 autosomes and two sex chromosomes (XY in the males and XX in the females). C-heterochromatic blocks were usually located in terminal and subterminal positions. Interstitial C-bands were exceptional. Each specimen exhibited a specific C-banding pattern, without intraindividual variation. Tables 1 and 2 and Figures 1 and 2 summarize the large variability observed in the C-banding karyotype of T. infestans from different localities. All populations showed variation in the number and/or the position of C-bands, allowing us to differentiate two clearly distinct groups. Group 1 includes insects from all Andean populations from Bolivia and Peru (70 specimens). The number of autosomes with C-blocks varied from 14 to 20, with a mean of 16.54 and a standard desviaton (SD) of 1.29 (Figure 2, parts D, E, and F; Table 1). Both sex chromosomes (X and Y) always presented C-bands but with different sizes (Figure 2E). Despite this variation, there was no clear difference in the number of chromosomes with C-bands among populations of the same localities but with different habitats (e.g., sylvatic and domestic populations from Jamach'Uma, Bolivia). Within group 1, the similar size and shape of the 10 chromosomal pairs made it very difficult to identify each pair. The C-heterochromatin content varied from 46% to 56% of the autosomal complement because of the heterochromatin polymorphism already mentioned. The mean haploid DNA content of all Andean specimens (12 insects) measured by flow cytometry was 1.825 [+ or -] 0.149 pg (Table 3). Group 2 includes specimens from all non-Andean populations, whose origins comprise three biogeographic bi·o·ge·og·ra·phy n. The study of the geographic distribution of organisms. bi  o·ge·og regions: Chaco (Bolivian and
Paraguayan Boreal bo·re·al adj. 1. Of or relating to the north; northern. 2. Of or concerning the north wind. 3. Boreal Chaco, and Austral aus·tral adj. Of, relating to, or coming from the south. [Latin austr  lis, from auster, austr-, south. Chaco of Argentina), Pampeana
(Uruguay), and Caatinga Caa`tin´gan. 1. (Phytogeography) A forest composed of stunted trees and thorny bushes, found in areas of small rainfall in Brazil. (Brazil) (Figure 2A, B, C; Figure 3). The number of autosomes with C-bands varied from four to seven chromosomes (mean 5.93 [+ or -] 0.45) (Table 1), but almost all of the 139 insects presented six C-heterochromatic autosomes (86.33%). In this group, the three first autosomal C-heterochromatic pairs were identified, based on size differences and meiotic configurations. The karyotype described in previous reports, BB BB AA, was by far the most frequent (Table 2 and Figure 3A). The Y chromosome always exhibited C-blocks, whereas the X chromosome X chromosome One of the two sex chromosomes (the other is Y) that determine a person's gender. Normal males have both an X and a Y chromosome, and normal females have two X chromosomes. did not show any C-banding (Figure 3A). The 30 specimens in this group measured by flow cytometry had a mean of 1.401 [+ or -] 0.111 pg of DNA per haploid nucleus (Table 3) in which the C-heterochromatin ranges from 24% to 30% of the total autosomal length. [FIGURE 2-3 OMITTED] Table 1 shows the number of C-heterochromatic autosomes in all samples studied. Table 2 details the C-banding patterns observed within non-Andean populations (group 2). The samples farthest away from the Andean region of Bolivia and Peru, e.g., the Brazilian Caatinga population, were the most homogeneous, almost always exhibiting the same C-karyomorphs (BB BB AA). By contrast, the population from the austral Chaco region of Argentina appeared quite variable, both in the number of C-banded autosomes as well as in the karyomorphs observed (Table 2). In the Andean population, we were unable to identify each chromosomal pair because of the similar size and shape of the autosomes. Table 3 summarizes the haploid DNA content (expressed in picograms) observed in different populations of T. infestans. When group samples were compared, a reduction of 30% from Andean to non-Andean populations was detected. When the Jamach'Uma Domestic sample (Andean Bolivia) was compared with the dark morph population (non-Andean Bolivia) (Table 3), the non-Andean population had 40% less haploid DNA content. Analysis of Experimental Progeny between Andean and Non-Andean Populations The meiotic behavior in the hybrids was apparently normal. A complete meiotic pairing was observed between the autosomes, and univalents were not detected (Figure 4). Several asymetric bivalents were clearly observed, formed by one chromosome with C-heterochromatin (one or two C-blocks) and another without C-heterochromatin (Figure 4). We could not detect any alteration in the form of the spermatids and spermatozoids. [FIGURE 4 OMITTED] Discussion Chromosomal Groups in T. infestans Our data disclosed two chromosomal groups in T. infestans here named Andean (Bolivian and Peruvian Andean samples) and non-Andean (samples from Argentina, Paraguay, Brazil, Uruguay, and Bolivian Chaco). These groups seem discrete and restricted to particular geographic areas; intermediate forms were not detected (Figure 1). These groups may be recognized by using three criteria: 1) the number of C-banded autosomes, 2) the C-banding on the X sex chromosome, and 3) the DNA content (Figures 2 and 3, Tables 1 and 2). The Andean specimens exhibited consistently more C-banded autosomes (14-20 autosomes) than non-Andean ones (4-7 autosomes); the Andean specimens showed a C-heterochromatic block in the X chromosome, which was absent in the non-Andean specimens, and all of them contained more DNA per cell (approximately 30% more) than did non-Andean specimens (Table 3). Taxonomic Status of T. infestans Populations Previous studies (8) suggested that heterochromatin could act as a fertility barrier in Triatominae by inhibiting meiotic pairing between chromosomes with different quantities of heteropyknotic regions. However, our analysis of experimental male progeny between both chromosomal groups (F1), where the chromosome pairing takes place without any apparent disturbance (Figure 4), shows that heterochromatin is not a postmating reproductive barrier, at least in T. infestans. Moreover, the subsequent developmental cycle and F1 fertility showed no difference with the parental generations (data not shown). Additional evidence for low level of divergence between these populations has been provided by other genetic techniques. Nei's standard genetic distance between Andean and non-Andean populations based on allozyme frequencies was low, generally under 0.050 (7), and the DNA sequence DNA sequence Genetics The precise order of bases–A,T,G,C–in a segment of DNA, gene, chromosome, or an entire genome. See Base pair, Base sequence analysis, Chromosome, Gene, Genome. comparison of a 412-bp fragment of the mitochondrial mitochondrial pertaining to mitochondria. mitochondrial RNAs a unique set of tRNAs, mRNAs, rRNAs, transcribed from mitochondrial DNA by a mitochondrial-specific RNA polymerase, that account for about 4% of the total cell RNA that cytochrome cytochrome (sī`təkrōm'), protein containing heme (see coenzyme) that participates in the phase of biochemical respiration called oxidative phosphorylation. B gene showed only three different nucleotide sites (14). At ribosomal DNA level, only 2 transversions and 4 insertions were found among the 459-bp-long ITS-2 (second internal transcribed spacer ITS (for internal transcribed spacer) refers to a piece of non-functional RNA situated between structural ribosomal RNAs (rRNA) on a common precursor transcript. Read from 5' to 3', this polycistronic rRNA precursor transcript contains the 5' external transcribed sequence (5' ETS), ) between populations from Bolivia (Andean) and Paraguay (Chaco) (15). These data suggest that the genetic variation in the two groups of T. infestans, despite their strong chromosomal and DNA content differences, could be attributable to intraspecies in·tra·spe·cif·ic also in·tra·spe·cies adj. Arising or occurring within a species: intraspecific competition. Adj. 1. variation. Biologic Significance of Heterochromatin Variation Eukaryotic eukaryotic /eu·kary·ot·ic/ (u?kar-e-ot´ik) pertaining to a eukaryon or to a eukaryote. eukaryotic pertaining to eukaryosis. eukaryotic cells see cell. genomic DNA contains highly repetitive sequences, the relative amounts of which can differ markedly at population and interspecies levels. Many of the changes in genome size can be attributed to variation in the abundance of these repetitive sequences, rather than to large differences in the nonrepetitive fraction of unique DNA (coding sequences included). C-heterochromatin, revealed by C-banding, consists largely of highly repetitive simple DNA sequences (satellite DNA satellite DNA n. A portion of DNA in animal cells whose density differs from that of the other DNA, consisting of short, repeating sequences of nucleotide pairs near the region of the centromere. ) and has long been regarded as inert or transcriptionally inactive. However, an extensive literature describes possible adaptive functions and effects of heterochromatin (16). An important and widespread effect of heterochromatin in germ cells both of plants and animals Plants and Animals are a Canadian indie-rock band from Montreal, comprised of guitarist-vocalists Warren Spicer and Nic Basque, and drummer-vocalist Matthew Woodley.[1] They are signed to Secret City Records. is its influence on the number and distribution of chiasmata. In most organisms, including T. infestans (13), the chiasmata either do not form, or form less frequently, in the euchromatic regions adjacent to the heterochromatin segments. Each heterochromatic het·er·o·chro·mat·ic adj. 1. Of or relating to heterochromatin. 2. Of or characterized by different colors; varicolored. 3. Consisting of different wavelengths or frequencies. block, through its chiasma chiasma (kīăz`mə): see crossing over. displacement effect, can keep in its proximity certain favorable allele allele (əlēl`): see genetics. allele Any one of two or more alternative forms of a gene that may occur alternatively at a given site on a chromosome. combinations of different genes ("coadapted co·a·dapt·ed adj. Of or relating to characteristics that have become established through mutually beneficial interactions between organisms in a community. co gene pools") (17). Deletion of C-block can release these zones, allowing recombination recombination, process of "shuffling" of genes by which new combinations can be generated. In recombination through sexual reproduction, the offspring's complete set of genes differs from that of either parent, being rather a combination of genes from both parents. to occur and causing certain allele combinations to disappear, generate new ones, or both and as a consequence, influence the adaptability of the individual insect. Variation in total DNA and heterochromatin contents has also been related to changes in biologic parameters, such as total cell volume, development rate, and body size (18). T. infestans specimens from Bolivia are indeed larger than those from Uruguay (7) or Brazil (19), suggesting that heterochromatin amounts could be related to morphologic parameters, and as a consequence, be the target of selective pressures (18). Origin of T. infestans Based mainly on the existence of sylvatic populations in the Cochabamba valleys of Bolivia, several authors (3,6,20) have suggested that T. infestans originated in these Andean valleys. On the other hand, Carcavallo et al. (21) suggested that the origin of this species was in the dry subtropical sub·trop·i·cal adj. Of, relating to, or being the geographic areas adjacent to the Tropics. subtropical Adjective of the region lying between the tropics and temperate lands forest from the South of Bolivia and Paraguay and the North of Argentina. This latter hypothesis was based on the discovery of sylvatic melanic me·lan·ic adj. 1. Of, relating to, or exhibiting melanism. 2. Of, relating to, or affected with melanosis; melanotic. forms of T. infestans ("dark morph") in the Bolivian Chaco (22). However, the proposal of the dark morph as the original T. infestans population was not supported by body size measurements (23), antennal sensilla patterns (24), or isoenzymatic and mitochondrial data (14). Furthermore, cytogenetic cytogenetic /cy·to·ge·net·ic/ (-je-net´ik) 1. pertaining to chromosomes. 2. pertaining to cytogenetics. cytogenetic pertaining to or originating from the origin and development of the cell. results indicated that in dark morph specimens heterochromatin is restricted to three autosomal pairs (25 and Table 2) and low DNA content (Table 3), suggesting their close relationship with our non-Andean chromosomal group. All these evidences strongly suggest that the dark morphs share a common origin with domestic non-Andean T. infestans and that they are not the original population, as suggested by Carcavallo et al. (21). Domestication Process Despite some controversy about the origin of T. infestans, researchers generally agree that the adaptation of this species to human dwellings began in the Andean regions of Bolivia. There, sylvatic T. infestans is found in rock piles associated with small mammals such as wild guinea pigs (Galea galea /ga·lea/ (ga´le-ah) [L.] a helmet-shaped structure. galea aponeuro´tica the aponeurosis connecting the two bellies of the occipitofrontalis muscle. musteloides) (4). Archaeological findings and historical reconstruction suggest that the domestication process occurred in pre-Colombian times, approximately 3,500 years ago (6), associated with the early settlements of pre-Incaic groups and the domestication of wild rodents for human food. The idea of a discrete Bolivian origin for domestic T. infestans is also supported by isoenzymatic studies (7,26). Hence, from Bolivia, domestic T. infestans spread over a major portion of South America. Geographic Spread of T. infestans in South America T. infestans does not fly over long distances and depends mainly on its vertebrate hosts for dispersal; thus, its geographic expansion was most probably associated with human migrations. The settlement of pre-Incaic and Incaic tribes and their spread over substantial Andean regions could be the first series of events allowing passive dispersal of T. infestans. However, most of the dispersal of this species appears to have been associated with post-Colombian economic migrations in South America, particularly during the last 100-150 years (6). In Uruguay for example, T. infestans appears to have reached some southern communities along the River Plate by 1865 (27), but it was unknown in northern departments of Uruguay Uruguay consists of 19 departments (departamentos, singular - departamento) (capitals in parentheses):
Origin and Spread of Chromosomal Groups Andean Dispersal In light of the historical context mentioned above, T. infestans was originally a sylvatic species with large quantities of heterochromatin distributed in most of its chromosomal pairs (autosomes and sex chromosomes). This cytogenetic attribute was not deeply affected during the first phase of its geographic expansion throughout the Andean region of Bolivia and Peru. The domestic specimens in this region constituted an extended population cytogenetically similar to their putative sylvatic original population in central Bolivia (Tables 1 and 3, Figure 2D, E, and F). Non-Andean Dispersal This dispersal in non-Andean regions involved T. infestans insects with a substantial loss of heteroehromatic regions. This reduction is the main cause of the decrease in the DNA size of these insects. Although the mechanisms involved in this heterochromatin loss and DNA size reduction are unknown, several processes have been proposed in other organisms, such as unequal exchange and spontaneous deletion in nonessential non·es·sen·tial adj. Being a substance required for normal functioning but not needed in the diet because the body can synthesize it. DNA (16,32). Non-Andean populations of T. infestans could have been established first by one or a few founders that eventually lost part of their heterochromatin by random genetic drill. This kind of founder effect seems to play an important role in the genetic structure of T. infestans populations, as has been suggested by isoenzyme isoenzyme /iso·en·zyme/ (-en´zim) isozyme. i·so·en·zyme n. See isozyme. i analysis (7,26,33). Moreover, the striking similarity among the C-banding patterns found in the non-Andean regions (Table 3), restricted to three heterochromatic pairs, suggests that the event of heterochromatin decrease may have taken place just once in the evolutionary history of T. infestans. This finding would imply that current populations of this insect outside Andean regions of Bolivia and Peru all derived from a single group of insects that were restricted to a particular region. Since Austral Chaco T. infestans in Argentina have the more variable C-banding patterns of the species from all the non-Andean areas (Table 1) and are geographically close to the Andean region, Austral Chaco was probably the primary focus of dispersal into the non-Andean region. The subsequent dispersion to other regions seems to have produced populations more homogeneous, in terms of number and localization Customizing software and documentation for a particular country. It includes the translation of menus and messages into the native spoken language as well as changes in the user interface to accommodate different alphabets and culture. See internationalization and l10n. of heterochromatic regions. Populations of recent colonization, such as those of Brazil and Uruguay, seem to have evolved towards the most common complement with three pairs of C-banded autosomes and a BB BB AA pattern (Figure 3A). In these populations, this karyotype is by far the most frequent and is the only one observed in the most recently colonized Colonized This occurs when a microorganism is found on or in a person without causing a disease. Mentioned in: Isolation zones such as the Piaui state in Brazil (Table 1). Genomic Changes and Adaptive Processes Genomic differentiation between both chromosomal groups is likely to be a reflection of both random drift and habitat adaptation. The novel genomic architecture of non-Andean group could have been triggered by a founder event. However, the success of these new small-genome insects is likely associated with adaptation to a new environment. One of the most noticeable differences in the domestic habitats of these groups is the altitude: Andean samples came from geographic regions generally above 1,800 m, whereas non-Andean populations were mainly from localities below 500 m (Table 1). Based on this geographic separation, our working hypothesis is that heterochromatin variation is a reflection of adaptive genomic changes that contribute to the ability of T. infestans to survive and reproduce in environments with different altitudes. According to this hypothesis, large-genome populations would be better adapted to Andean (highland) domiciles, while populations with small genomes would do better in non-Andean (lowland) houses. As a consequence, the success and spreading of each chromosomal group into Andean and non-Andean regions may indicate a better adaptation to the different selective pressures of its environment. A positive correlation between chromosome number and heterochromatin content with altitude has been described in other organisms (34,35). Nevertheless, other possible environmental factors or climatic variables associated with Andean and non-Andean habitats should not be discarded. The inability to detect both chromosomal groups in a same region may also suggest a possible competition between them. The success of one chromosomal group with respect to the other would then depend on altitude. However, large-genome insects would be able to colonize lowlands, and small-genome insects would be able to colonize highlands. This suggestion would explain the colonization by small-genome T. infestans of Argentina highlands (as we observed in the Anillaco sample). According to our altitude hypothesis, the Anillaco region should be a primary focus of colonization by T. infestans (small genomes), not previously colonized by large-genome insects. The analysis of very close locations with different altitudes in southern Bolivia and northern Argentina would contribute to testing our hypothesis that DNA content reduction reflects adaptive genomic changes related to altitude. The adaptation of small genome insects to non-Andean domiciles could also be related to a loss in their capacity to return to sylvatic habitats. In non-Andean regions, T. infestans does not exhibit sylvatic foci, with the exception of atypical dark morph and melanosoma melanic variants (14,22). These facts could suggest that small-genome insects are unable to adapt to non-Andean sylvatic environments, unless they undergo new genetic changes that influence morphologic parameters. In summary, we proposed that the genome size decrease observed in T. infestans was a successful change as it underwent adaptation to domiciles located in non-Andean lowland regions. However, the founder event generating this genomic variant could have also implied some loss of variability in particular loci loci [L.] plural of locus. loci Plural of locus, see there . Greater domestic dependence, the inability to return to sylvatic ecotopes, and a certain degree of reduced variability could contribute to making these insects more susceptible to control campaigns, as observed in Uruguay, Chile, and Brazil. In future studies, socioeconomic, environmental, and operational issues also have to be taken into account so that the influence of vector genetic changes in control strategies can be evaluated. Furthermore, the existence of two allopatric groups in T. infestans with notable genomic differences is an important feature that have to be considered in evaluating vector control campaigns as well as in selecting the insect used in any genetic studies, including genome sequencing projects.
Table 1. Analyzed material of Triatoma infestans classified by
procedence, biogeographic region, altitude, number of specimens
analyzed (n) with C-banding, and number of autosomes with C-bands
(mean and standard deviation)'
Country Department, province, Biogeographic
locality; habitat (b); region (c)
y collected
Bolivia La Paz, Murillo, Palomar. Andes [1]
D. 1997
Bolivia La Paz, La Paz, Rio Abajo. Andes [2]
D. 1997
Bolivia Cochabamba, Esteban Arze, Andes [3]
Jamach'Uma. D. 1997
Bolivia Cochabamba, Esteban Ante, Andes [3]
Janiach'Uma. S. 1997
Bolivia Chuquisaca, Yamparaez, Andes [4]
Uyuni. D. 1997
Peru Arequipa, Arequipa city. Andes [5]
D. 1997
Bolivia Cochabamba, Campero, Pena Andes [6]
Colorada. D. 1997
Bolivia Santa Cruz, Florida, Pampa Andes [7]
Grande. D. 1997
Argentina La Rioja, Anillaco. P. 1997 Austral Chaco [8]
Brazil Bahia, Paratinga. D. 1995 Caatinga [9]
Brazil Piaui, Caracul. D. 1996 Caatinga [10]
Bolivia Santa Cruz, Cordillera, Boreal Chaco [11]
Izozog. D. 1997
Bolivia Santa Cruz, Cordillera, Boreal Chaco [11]
Izuzog. S. "Dark morphs."
1997
Paraguay Chaco, Rio Negro. D. 1997 Boreal Chaco [12]
Argentine Cordoba, Cruz del Eje, Austral Chaco [13]
Los Leones. D & P. 2000
Argentine Santiago del Estero, Moreno, Austral Chaco [14]
San Pablo. P. 1999
Uruguay Several populations from Pampcana [15,16]
Southern and Northern.
D & P.1988-1995
Country Altitude N (M,F) (d) No. of C-autosomes
(m) mean and SD
Bolivia 3,000 3 M 18.00 [+ or -] 2.00
Bolivia 2,900 16 M 17.00 [+ or -] 1.03
Bolivia 2,700 15 M, 3 F 15.72 [+ or -] 1.49
Bolivia 2,700 7 M, 2 F 16.00 [+ or -] 0.87
Bolivia 2,542 9 M 17.44 [+ or -] 0.88
Peru 2,336 8 M 16.63 [+ or -] 1.06
Bolivia 1,890 3 M 16.00 [+ or -] 0.00
Bolivia 1,250 4 M 16.75 [+ or -] 0.50
Argentina 1,400 5 M 6.20 [+ or -] 0.45
Brazil 500 9 M 6.00 [+ or -] 0.00
Brazil 450 6 M, 8 F 6.00 [+ or -] 0.00
Bolivia 350 2 M 7.00 [+ or -] 0.00
Bolivia 350 8 M 6.00 [+ or -] 0.00
Paraguay 350 6 M, 3 F 6.33 [+ or -] 0.50
Argentine 250 12 M 5.17 [+ or -] 0.58
Argentine 200 7 M, 3 F 5.50 [+ or -] 0.85
Uruguay 200 44 M, 26 F 5.99 [+ or -] 0.12
(a) All specimens camue from natural populations. Statistically
significant differences (p < 0.001) were detected in the number
of C-autosomes between Andean (16.54 [+ or -]
1.29) and non-Andean (5.93 1 0.45) grouped samples.
(b) P, peridonticifary: D, domiciliary: S, sylvalic.
(c) Numbers in brackets refer to the location of the populations
in Figure I.
(d) M, males; F, teinales.
Table 2. C-banding patterns observed in the three largest autosomal
pairs of Triatoma infestans from the non-Andean populations
analyzed (a)
C-banding Argentina Bolivia and Uruguay
pattern (Austral Chaco) Paraguay (Boreal) (Pampeana)
[8][13][14] (b) Chaco)[11,12] [15,16]
BB BB BB -- 1 --
BB BB AB 1 7 6
BB BB AA 1 3 43
BB BB AC 1 -- 1
BB AB AA 4 -- 16
BB AA AA 4 1 (a) 4
BB AA AC 3 -- --
BB AB AC 2 -- --
BB AB CC 2 -- --
BB AA CC 1 -- --
AB BB AA 1 -- --
AB AB AA 2 -- --
AB AB AC 3 -- --
AB AA AB 1 -- --
AB AA AA 2 3 (c) --
AA AA AA -- 4 (c) --
Total 27 19 70
C-banding Brazil Total
pattern (Caatinga) specimens
[9,10]
BB BB BB -- 1
BB BB AB -- 14
BB BB AA 21 68
BB BB AC -- 2
BB AB AA 1 21
BB AA AA 1 10
BB AA AC -- 3
BB AB AC -- 2
BB AB CC -- 2
BB AA CC -- 1
AB BB AA -- 1
AB AB AA -- 2
AB AB AC -- 3
AB AA AB -- 1
AB AA AA -- 4
AA AA AA -- 4
Total 23 139
(a) The population more near the Andean region of Bolivia and Peru,
e.g., the Austral Chaco region of Argentine, appeared very variable
both in the number of C-banded autosomes and in the karyomorphs
observed. By contrast, the samples farthest away from the Andean
region, e.g.. Brazilian Caatinga populations, were the most
homogeneous, almost always exhibiting the same C-karyomorphs
(BB BB AA).
(b) Numbers in brackets refer to the location of the populations
in Figure 1.
(c) Sylvatic (dark morpins).
Table 3. Haploid DNA contents (C-value) expressed in pg (mean and
standard deviation), measured by flow cytometry, in 42 Triatoma
intestans specimens from different populations"
Origin Population analyzed (b) n
Bolivia (Andean) Jamach'Uma. D. [3] 4
Bolivia (Andean) Jamach'Uma. S. [3] 4
Bolivia (Andean) Rio Abajo. D. [2] 4
Paraguay (non-Andean) Chaco. D.[12] 4
Brazil (non-Andean) Caracol and Paratinga. 3
D. [9,10]
Uruguay (non-Andean) Northern populations. 13
P. D. [16]
Argentine (nun-Andean) Cruz del Eje and Moreno. 6
P. D. [13,14]
Bolivia (non-Andean) Santa Cruz. S. Dark 4
morphs [11]
Origin Haploid DNA
content mean
and SD (pg) (c)
Bolivia (Andean) 1.842 [+ or -] 0.201
Bolivia (Andean) 1.835 [+ or -] 0.140
Bolivia (Andean) 1.799 [+ or -] 0.140
Paraguay (non-Andean) 1.494 [+ or -] 0.170
Brazil (non-Andean) 1.420 [+ or -] 0.041
Uruguay (non-Andean) 1.414 [+ or -] 0.106
Argentine (nun-Andean) 1.352 [+ or -] 0.094
Bolivia (non-Andean) 1.320 [+ or -] 0.046
(a) n, number of specimens analyzed; P, periodomiciliary; D,
domiciliary; S, sylvatic.
(b) Numbers in brackets refer to the location of the populations
in Figure 1.
(c) Significant differences
Acknowledgments We thank C.J. Schofield, A. Rojas de Arias, S. Catala, F. Noireau, L. Diotaiuti, and H.R. Pires for their invaluable collaboration and for providing several of the specimens. We also thank A.C. Silveira and D. Canale for providing some additional specimens. This work was partially supported by Comision Sectorial de Investigacion Cientifica (CSIC (Customer Specific Integrated Circuit) Pronounced "c-sick." Another term for ASIC, which was coined by Motorola. Some feel this is a more accurate description of an ASIC chip. See ASIC. ), Proyecto de Desarrollo de Ciencias Basicas (PEDECIBA), and Consejo Nacional de Investigaciones Cientificas y Tecnicas (CONICYT CONICYT Commission Nacional de Investigación Cientifica y Tecnológica (Chile) )(Fondo Clemente Estable, Project 2034) from Uruguay. Additional financial support was provided through the European Community Latin American network for research on Triatominae (ECLAT) and European South America Public Health (EUSAPH) networks from the Commission of the European Communities. F. Panzera benefited from additional funding by the Conselleria de Cultara i Educacio of the Generalitat Valenciana and the University of Valencia The University of Valencia (official name in Catalan Universitat de València) is a Spanish university, located in the city of Valencia. The Universitat de València is one of the oldest and largest universities in Spain, having been founded in 1499 and currently , Spain. The observations and photographs were made on Nkong photomicroscopes donated by the government of Japan. References (1.) World Health Organization. Control of Chagas disease. Second report of the WHO Expert Committee. World Health Organization Technical Report Series. Geneva Geneva, canton and city, Switzerland Geneva (jənē`və), Fr. 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Caryologia 1997;50:97-103. Francisco Panzera, * Jean Pierre Dujardin, ([dagger]) Paula Nicolini, * Maria Noel Caraccio, * Virginia Rose, * Tatiana Tellez, ([subsection]) Hernan Bermudez, Maria Dolores Dolores (or Delores) was a common given name (until the 1960s in the USA); it is cognate with the English word "dolorous" (meaning sorrowful) and equivalent in meaning. Bargues, ([section]) Santiago Mas-Coma, ([section]) Jose Enrique O'Connor, ([section]) and Ruben Perez * * Universidad Mayor de la Republica, Montevideo, Uruguay; ([dagger]) Institut de Recherche re·cher·ché adj. 1. Uncommon; rare. 2. Exquisite; choice. 3. Overrefined; forced. 4. Pretentious; overblown. pour le Developpement, Montpellier, France; ([subsection]) Universidad Mayor de San Simon, Cochabamba, Bolivia; and ([section]) Universidad de Valencia, Valencia, Spain Dr. Panzera is a professor of evolutionary genetics at the Faculty of Sciences of Montevideo (Uruguay). His research interests focus on the genetics of insects, particularly triatomines, with relevance to Chagas disease vectors. He directs a reference center laboratory on cytogenetic studies in the European Community Latin American network for research on Triatominae (ECLAT) (available from: www.eclat.fcien.edu.uy). Address for correspondence: Francisco Panzera, Instituto de Biologia, Seccion Genetica Evolutiva, Facultad de Ciencias, Igua. 4225, 11400 Montevideo, Uruguay; fax: (5982)-525-86-17/31; email: panzera@fcien.edu.uy |
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