Geographic Distribution and Genetic Diversity of Whitewater Arroyo Virus in the Southwestern United States.The purpose of this study was to extend our knowledge of the geographic distribution and genetic diversity of the arenavirus arenavirus /are·na·vi·rus/ (ah-re´nah-vi?rus) any virus of the family Arenaviridae. Arenavirus /Are·na·vi·rus/ (ah-re´nah-vi?rus) arenaviruses; a genus of viruses of the family Arenaviridae that includes lymphocytic choriomeningitic (LCM) virus, Lassa virus, and viruses of the Tacaribe complex.(es) associated with Neotoma species (woodrats) in the southwestern United States. Infectious arenavirus was recovered from 14 (3.3%) of 425 woodrats. The virus-positive species included N. albigula in New Mexico and Oklahoma, N. cinerea cinerea /ci·ne·rea/ (si-ne´re-ah) the gray matter of the nervous system.cine´real ci·ne·re·a (s  -nîr in Utah, N. mexicana in New Mexico and Utah,
and N. micropus in Texas. Analyses of viral nucleocapsid protein gene
sequence data indicated that all the isolates were strains of the
Whitewater Arroyo virus, an arenavirus previously known only from
northwestern New Mexico. Analyses of the sequence data also indicated
that there can be substantial genetic diversity among strains of
Whitewater Arroyo virus from conspecific woodrats collected from
different localities and substantial genetic diversity among strains
from different woodrat species collected from the same locality.The virus family Arenaviridae Arenaviridae /Are·na·vi·ri·dae/ (ah-re?nah-vir´i-de) the arenaviruses; a family of RNA viruses with a pleomorphic virion and a genome consisting of two circular molecules of single-stranded RNA. The single genus is Arenavirus. Ar·e·na·vir·i·dae comprises two serocomplexes. The lymphocytic choriomeningitis lymphocytic choriomeningitis viral meningitis, occurring in adults between the ages of 20 and 40, during the fall and winter. cho·ri·o·men·in·gi·tis (kôr   --Lassa (Old World) complex includes
lymphocytic choriomeningitis (LCM), Lassa, Mopeia, Mobala, and Ippy
viruses. The Tacaribe (New World) complex includes Tamiami (TAM),
Whitewater Arroyo (WWA), Pichinde (PIC), Amapari, Flexal, Guanarito,
Junin, Latino, Machupo, Oliveros, Parana, Pirital, Sabia, and Tacaribe
viruses.The arenaviruses have bipartite bi·par·tite (b  -pärtt)adj. , single-stranded RNA genomes (1).
The large (L) genomic segment encodes the viral RNA-dependent RNA
polymerase and a zinc-binding protein. The small (S) genomic segment
encodes the nucleocapsid (N) protein and glycoprotein precursor. The
most comprehensive knowledge of the phylogeny of the family Arenaviridae
is based on a fragment of the N protein gene (2-4).Six arenaviruses are known to cause severe disease in humans. LCM virus is an agent of acute central nervous system disease (5) and congenital malformations (6). Lassa, Junin, Machupo, Guanarito, and Sabia viruses are etiologic agents of hemorrhagic fever in western Africa, Argentina, Bolivia, Venezuela, and Brazil, respectively (7). The arenaviruses known to occur in North America are LCM, TAM, and WWA. LCM virus was introduced into the Americas along with its principal rodent host, Mus musculus (house mouse) (8). TAM virus is known only from Sigmodon hispidus (hispid cotton rat) in southern Florida (9-11). WWA virus was originally recovered from Neotoma albigula (white-throated woodrat) collected from northwestern New Mexico (12). In a recent study (13), antibody to an arenavirus was found in five Neotoma species in the southwestern United States: N. albigula in Arizona, Colorado, and New Mexico; N. stephensi (Stephen's woodrat) in Arizona and New Mexico; N. mexicana (Mexican woodrat) in Arizona and Utah; and N. fuscipes (dusky-footed woodrat) and N. lepida (desert woodrat) in California. The purpose of the present study was to extend our knowledge of the geographic distribution and genetic diversity of the arenavirus(es) associated with Neotoma rodents in the southwestern United States. Materials and Methods All work with rodent tissues and infectious arenavirus was performed in a biosafety level 3 laboratory at the Centers for Disease Control and Prevention (Atlanta, GA) or University of Texas Medical Branch, Galveston. Rodent Tissues Five hundred sixty-six tissue specimens (74 spleen, 225 liver, and 267 kidney) from 425 woodrats were tested for infectious arenavirus. The specimens were from the Museum of Texas Tech University (Lubbock, TX) or Museum of Southwestern Biology (University of New Mexico, Albuquerque, NM). The specimens from the Museum of Southwestern Biology were chosen to represent localities in which antibody to an arenavirus was found in one or more Neotoma species in a previous study (13). Virus Assay Tissue specimens were tested for infectious arenavirus as described previously (12). Briefly, 0.2 mL of a 10% w/v crude tissue homogenate was inoculated onto a monolayer of Vero E6 cells in a 25-[cm.sup.2] plastic culture flask (Corning, Inc., Corning, NY). The inoculum was incubated on the cell monolayer at 37 [degrees] C for 60 minutes; then the monolayer was overlaid with 7.0 mL of a minimum essential medium containing Earle's salts, 1.5 mg/mL sodium bicarbonate, 2% v/v heat-inactivated (56 [degrees] C for 30 minutes) fetal bovine serum, 0.29 mg/mL L-glutamine Glu , 100 U/mL penicillin G, 100 [micro]g/mL
streptomycin sulfate, and 100 U/mL nystatin. The cell culture was
maintained at 37 [degrees] C in a humidified atmosphere of 5% CO2 in air
for 13 days. Half the culture medium was replaced with fresh maintenance
medium on day 6 or 7 after inoculation. Cells were scraped from the
monolayer on day 13 after inoculation and coated onto 12-well glass
microscope slides (Cel-Line Associates, Inc., Newfield, NJ). The cell
spots were air-dried, fixed in cold acetone, and then tested for
arenaviral antigen by using an indirect fluorescent antibody test (12).
In that test, cell spots were stained with a hyperimmune mouse ascitic
fluid prepared against the WWA virus prototype strain AV av avoirdupois; see avoirdupois weight, under weight. A nonessential amino acid that occurs widely in proteins and blood and other tissue and is metabolized to yield urinary ammonia. Also called glutaminic acid. AV, A-V atrioventricular; arteriovenous. 9310135, and mouse immunoglobulin G (IgG) bound to cell-associated arenaviral antigen was detected by using a goat anti-mouse IgG fluorescein isothiocyanate conjugate (Cappel Laboratories, West Chester, PA). Genetic Characterization of Viral Isolates The nucleotide sequence of a fragment of the N protein gene of each of 12 isolates was determined. Four of the 12 isolates were from the spleens and kidneys of two animals, rodents 62425 and 62439 (Table 1). Total RNA was extracted from monolayers of infected Vero E6 cells by using TRIzol Reagent (Life Technologies, Inc., Grand Island, NY). Reverse transcription of RNA from isolates AV 96010149, AV 96010151, AV 96010025, and AV 96010024 was carried out by using Superscript II RTase (Life Technologies) in conjunction with oligonucleotide ARE-3'END (14). This oligonucleotide apparently is complementary to the 19-nt fragment at the 3' terminus of the S genomic segment of all arenaviruses. Polymerase chain reaction (PCR) amplification of the first-strand cDNA was carried out by using Taq DNA polymerase (Promega Corp., Madison, WI) in conjunction with oligonucleotides 1010C and NW1696R (2-3), which flank a 616-nt region of the N protein gene of WWA virus prototype strain AV 9310135 (12). Reverse transcription and PCR (RT-PCR) amplification of a fragment of the N protein gene of each of the eight other isolates was carried out by using the Access RT-PCR Kit (Promega Corp.) in conjunction with oligonucleotides AVNP1 (5'-CCCTTCTTYTTNYTCTTRATGACTA-3') and AVNP2 (5'-GGKAGRGCNTGGGAYAACAC-3'). AVNP1 and AVNP2 flank a 518mt region in the fragment of the WWA virus N protein gene that is amplified by using oligonucleotides 1010C and NW1696R. They were designed based on N protein gene sequence data for the WWA virus prototype strain AV 9310135 (GenBank Accession No. U52180), WWA virus strains AV 96010149, AV 96010151, AV 96010025, and AV 96010024, TAM virus strain W-10777 (U43690), and PIC virus strain An 3739 (K02734). Size separation of PCR products was done by agarose gel electrophoresis; the products of the expected size were purified from gel slices by using QIAquick Gel Extraction Kit (Qiagen, Inc., Valencia, CA). One strand of each 1010C-NW1696R PCR product was sequenced directly by using the dye termination cycle sequencing technique (Applied Biosystems, Inc., Foster City, CA) in conjunction with oligonucleotide 1010C. The sequence of the other (i.e., complementary) strand of each of these products was determined by cloning the PCR product in the TA cloning vector PCRII (Invitrogen Corp., Carlsbad, CA) and then using a plasmid-specific oligonucleotide (M13) to initiate the cycle sequencing reaction. Both strands of the AVNP1-AVNP2 PCR products were sequenced directly by using the same oligonucleotides that were used to prime the RT-PCR, i.e., AVNP1 and AVNP2. The 12 nucleotide sequences generated in this study were deposited with the GenBank nucleotide sequence database under Accession Nos. AY012710-AY012721.
Table 1. Recovery of infectious arenavirus from tissues
of virus-positive woodrats (Neotoma species)
Collected from
Date
Rodent Species collected County State
1627 N. albigula 07/15/93 McKinley NM
1626 N. albigula 07/15/93 McKinley NM
62415 N. mexicana 09/24/94 Socorro NM
62425 N. mexicana 09/24/94 Socorro NM
62439 N. mexicana 09/24/94 Socorro NM
28731 N. albigula 10/12/85 Cimarron OK
28742 N. albigula 10/12/85 Cimarron OK
84648 N. micropus 07/18/99 Dimmit TX
84703 N. micropus 07/19/99 Dimmit TX
84708 N. micropus 07/19/99 Dimmit TX
84761 N. micropus 07/18/99 Dimmit TX
84816 N. micropus 07/20/99 La Salle TX
36287 N. cinerea 07/06/94 San Juan UT
36282 N. mexicana 07/05/94 San Juan UT
Virus (strain) recovered from(a)
Rodent Species Spleen Kidney Liver
1627 N. albigula AV 9310041 AV 9310135 nt
1626 N. albigula nt AV 9310040 nt
62415 N. mexicana nt AV 96010149 nt
62425 N. mexicana nt AV 96010151 AV 98360019
62439 N. mexicana nt AV 96010154 AV 98360020
28731 N. albigula nt AV 98490013 Negative
28742 N. albigula nt AV 97130039 TVP-6038
84648 N. micropus Negative AV A0400098 nt
84703 N. micropus AV A0400337 AV A0400135 nt
84708 N. micropus nt AV A0400140 nt
84761 N. micropus AV A0400373 AV A0400174 nt
84816 N. micropus AV A0400412 AV A0400212 nt
36287 N. cinerea nt AV 96010025 AV 96010206
36282 N. mexicana nt AV 96010024 AV 96010205
(a) nt = not tested. The WWA virus prototype strain is bolded.
Isolates (strains) included in the (phylo-) genetic analyses
are underlined.
Data Analysis The analyses of nucleotide sequence data were restricted to the 518-nt fragment of the WWA virus N protein gene that is flanked by oligonucleotides AVNP1 and AVNP2. The GenBank database sequences included in the analyses were Accession Nos. U52180 (WWA virus, strain AV 9310135), U43690 (TAM, W-10777), K02734 (PIC, An 3739), U43689 (Parana, 12056), U43687 (Flexal, BeAn 293022), U62561 (Pirital, VAV-488), U43688 (Latino, 10924), U34248 (Oliveros, 3229-1), U70802 (Junin, XJ), X62616 (Machupo, AA288-77), U43686 (Guanarito, INH-95551), U41071 (Sabia, SPH 114202), U43685 (Amapari, BeAn 70563), M20304 (Tacaribe, TRVL 11573), M20869 (LCM, Armstrong), and U80004 (Lassa, LP). The computer software package CLUSTAL W1.7 (15) was used to construct an alignment of the predicted amino acid sequences, and the computer program TransAlign (16) was used to generate a multiple nucleotide sequence alignment from the amino acid sequence alignment. Pairwise genetic distances were computed by using the p distance model as implemented in the computer program MEGA, version 1.02 (17). Percent sequence identities were calculated by subtracting the genetic distances from 1.0 and multiplying by 100. Phylogenetic analysis was carried out on the multiple amino acid sequence alignment by using the neighbor-joining method (gamma model, alpha = 2) as implemented in MEGA, version 1.02. Bootstrap support (18) for the results of the phylogenetic analysis was based on 500 pseudoreplicate datasets generated from the original multiple amino acid sequence alignment. Results Viral Isolates Twenty-three arenaviral isolates were recovered from tissues of 14 (3.3%) of 425 Neotoma rodents (Table 1). The 23 isolates included three WWA virus strains (AV 9310135, AV 9310041, and AV 9310040) that were reported previously (12). The virus-positive animals included two N. albigula from McKinley County, northwestern New Mexico; two N. albigula from Cimarron County, western Oklahoma; three N. mexicana from Socorro County, central New Mexico; five N. micropus from the Chaparral Wildlife Management Area (Dimmit and La Salle counties), southern Texas; and one N. mexicana and one N. cinerea from San Juan County, southeastern Utah (Table 2, Figure 1). The virus-positive animals from McKinley County were two (50%) of four woodrats (all N. albigula) collected on July 15, 1993, from Whitewater Arroyo. The positive N. albigula from Cimarron County were two (22.2%) of nine woodrats (seven N. albigula and two N. mexicana) collected on October 12, 1985, from a site near Kenton. The positive N. mexicana from Socorro County were three (42.9%) of seven woodrats (all N. mexicana) collected on September 24, 1994, from a site in the Magdalena Mountains. The positive N. micropus from Dimmit County were 4 (13.8%) of 29 woodrats (all N. micropus) collected in a 3-day period (July 17 through July 19, 1999) from the western region of the Chaparral Wildlife Management Area. The positive N. micropus from La Salle County was one (25.0%) of four woodrats (all N. micropus) collected on July 20, 1999, from the eastern region of the Chaparral Wildlife Management Area. The positive N. mexicana and N. cinerea from San Juan County were 2 (12.5%) of 16 woodrats (11 N. mexicana, 2 N. cinerea, and 3 N. albigula) collected in an 8-day period (June 29 through July 6, 1994) from Natural Bridges National Monument. Information from the Museum of Southwestern Biology indicated that the positive N. mexicana and N. cinerea were collected from different sites in Natural Bridges National Monument. [Illustration omitted]
Table 2. Results of virus isolation
attempts on tissues from 425 woodrats
Neotoma species(a)
County(b) State Nalb Ncin Nflo
Apache (1) AZ -- -- --
Cochise (2) AZ 0/31 -- --
Coconino (2) AZ 0/6 -- --
Maricopa (1) AZ 0/23 -- --
Navajo (1) AZ 0/29 0/1 --
Yavapai (2) AZ 0/5 -- --
McKinley (3) NM 2/16 -- --
Otero (9) NM 0/33 -- --
Socorro (3) NM 0/31 -- --
Cimarron (4) OK 2/11 -- --
Major (4) OK -- -- 0/45
McIntosh (2) OK -- -- 0/12
Pottawatomie (2) OK -- -- 0/7
Dimmit (1) TX -- -- --
La Salle (1) TX -- -- --
San Juan (8) UT 0/3 1/2 --
Total 4/188 1/3 0/64
Neotoma species(a)
County(b) Nme Nmic Nste Total
Apache (1) 0/6 -- 0/5 0/11
Cochise (2) -- -- -- 0/31
Coconino (2) -- -- 0/3 0/9
Maricopa (1) -- -- -- 0/23
Navajo (1) 0/5 -- 0/7 0/42
Yavapai (2) 0/2 -- -- 0/7
McKinley (3) -- -- -- 2/16
Otero (9) 0/9 0/35 -- 0/77
Socorro (3) 3/10 0/1 -- 3/42
Cimarron (4) 0/5 -- -- 2/16
Major (4) -- 0/38 -- 0/83
McIntosh (2) -- -- -- 0/12
Pottawatomie (2) -- -- -- 0/7
Dimmit (1) -- 4/29 -- 4/29
La Salle (1) -- 1/4 -- 1/4
San Juan (8) 1/11 -- -- 2/16
Total 4/48 5/107 0/15 14/425
(a) Nalb = Neotoma albigula, Ncin = N. cinerea, Nflo = N.
floridana, Nmex = N. mexicana, Nmic = N. micropus,
Nste = N. stephensi. Values are the number positive/number
tested; "-" = none tested.
(b) Number in parentheses indicates the number
of sites sampled in the county.
The nucleotide sequences of the isolates from rodent 62425 (one isolate each from kidney and liver; strains AV 96010151 and AV 98360019, respectively) were identical. In contrast, the nucleotide sequences of the isolates from rodent 62439 (again, one isolate each from kidney and liver; strains AV 96010154 and AV 98360020, respectively) were 99.6% identical. Further study is needed to determine whether the differences between the isolates from rodent 62439 represent the coexistence of multiple virus genotypes (alleles) in the same rodent. An alternative explanation is that the sequence differences are the result of adaptation of the isolates to growth in cultured (Vero E6) cells or manipulation of viral nucleic acid extracted from cultured cells. Nucleotide and amino acid sequence identities among WWA virus prototype strain AV 9310135 and 12 other isolates from Neotoma rodents ranged from 74.7% to 100.0% and 84.9% to 100.0%, respectively (Table 3). When compared with other arenaviruses, the isolates from the Neotoma rodents exhibited 69.9% to 73.7% nucleotide sequence identity with TAM virus, 61.0% to 63.3% identity with PIC virus, and less than 62.0% sequence identity with all other arenaviruses.
Table 3. Nucleotide and amino acid sequence identities
among 13 arenavirus isolates recovered from
11 woodrats and Tamiami virus(a)
Virus or strain
AV 93 AV 93 AV 96 AV 96
Virus(b) Strain 10135 10040 10149 10151
WWA AV 9310135 -- 100.0 86.5 86.5
WWA AV 9310040 100.0 -- 86.5 86.5
WWA AV 96010149 95.3 95.3 -- 100.0
WWA AV 96010151 95.3 95.3 100.0 --
WWA AV 98360019 95.3 95.3 100.0 100.0
WWA AV 96010154 94.8 94.8 98.8 98.8
WWA AV 98360020 95.3 95.3 99.4 99.4
WWA AV 98490013 91.9 91.9 90.7 90.7
WWA TVP-6038 91.9 91.9 90.7 90.7
WWA AV A0400212 88.4 88.4 88.9 88.9
WWA AV A0400174 88.9 88.9 89.5 89.5
WWA AV 96010025 90.7 90.7 91.3 91.3
WWA AV 96010024 93.0 93.0 94.2 94.2
TAM W-10777 77.9 77.9 78.5 78.5
Virus or strain
AV 98 AV 96 AV 98 AV 98 TVP-
Virus(b) 360019 10154 360020 490013 6038
WWA 86.5 85.3 85.3 82.3 82.6
WWA 86.5 85.3 85.3 82.3 82.6
WWA 100.0 98.1 98.5 80.1 80.3
WWA 100.0 98.1 98.5 80.1 80.3
WWA -- 98.1 98.5 80.1 80.3
WWA 98.8 -- 99.6 81.3 81.5
WWA 99.4 99.4 -- 81.3 81.5
WWA 90.7 90.7 91.3 -- 99.4
WWA 90.7 90.7 91.3 98.8 --
WWA 88.9 88.9 89.5 86.6 86.6
WWA 89.5 89.5 88.9 85.5 85.5
WWA 91.3 91.3 91.3 87.8 87.8
WWA 94.2 94.2 94.2 88.4 88.4
TAM 78.5 78.5 78.5 78.5 78.5
Virus or strain
AV A0 AV A0 AV 96 AV 96 TAM
Virus(b) 400212 400174 10025 10024
WWA 79.1 79.1 83.4 85.1 71.6
WWA 79.1 79.1 83.4 85.1 71.6
WWA 79.5 78.8 84.4 85.5 73.7
WWA 79.5 78.8 84.4 85.5 73.7
WWA 79.5 78.8 84.4 85.5 73.7
WWA 79.3 78.6 84.4 85.1 73.2
WWA 79.5 78.8 84.4 85.1 73.4
WWA 79.0 77.8 80.9 80.7 72.2
WWA 79.1 78.0 81.1 80.1 72.4
WWA -- 95.7 77.2 77.0 69.9
WWA 98.3 -- 74.7 75.5 69.9
WWA 84.9 84.9 -- 82.8 71.6
WWA 86.0 86.0 89.5 -- 72.2
TAM 80.2 80.2 77.3 78.5 --
(a) Nucleotide and amino acid sequence identities
are listed above and below the dashes, respectively.
(b) WWA = Whitewater Arroyo, TAM = Tamiami.
Phylogenetic analysis of N protein amino acid sequence data indicated that isolates from Neotoma rodents represent a phylogenetic lineage (viral species) that is in a sister relationship to the lineage represented by TAM virus (Figure 2). We concluded that all isolates recovered from the Neotoma rodents were strains of WWA virus. [Illustration omitted] Discussion Before the present study, WWA virus was known only from N. albigula in northwestern New Mexico (12). The present work provides unequivocal evidence that the virus also is naturally associated with N. cinerea, N. mexicana, and N. micropus, and that it occurs in Utah, central New Mexico, Oklahoma, and Texas. The recovery of WWA virus strains AV 98490013 and TVP-6083 from N. albigula is the first evidence that a Tacaribe complex virus occurs in Oklahoma. Likewise, the recovery of strains AV A0400174 and AV A0400212 from woodrats collected from southern Texas (Chaparral Wildlife Management Area) is the first evidence that N. micropus is naturally associated with a Tacaribe complex virus and that WWA virus occurs in Texas. In a previous study (13), antibody to an arenavirus was found in N. fuscipes and N. lepida in southern California; N. albigula, N. mexicana, and N. stephensi in Arizona; and N. albigula in southwestern Colorado. Although the results of the present study indicate that WWA virus is geographically widely distributed in association with Neotoma rodents, further work is needed to determine whether the arenavirus associated with Neotoma rodents in California, Arizona, and Colorado is in fact WWA virus. The results of the present study indicate that there can be substantial genetic heterogeneity among strains of WWA virus from different woodrat species from the same locality and among strains from conspecific woodrats collected from different localities. For example, nucleotide sequence identity between the strains recovered from N. mexicana and N. cinerea from Natural Bridges National Monument (San Juan County, Utah; strains AV 96010024 and AV 96010025, respectively) was 82.8%, and nucleotide sequence identity between strain AV 96010024 and the three strains recovered from N. mexicana collected from the Magdalena Mountains (Socorro County, New Mexico; strains AV 96010149, AV 96010151, and AV 96010154) was from 85.1% to 85.5%. In contrast, nucleotide sequence identity in strains recovered from conspecific rodents collected from the same locality (e.g., strains AV 9310135 and AV 9310040 from N. albigula from Whitewater Arroyo, and strains AV A0400174 and AV A0400212 from N. micropus from the Chaparral Wildlife Management Area) was [is greater than] 95.0%. The results of previous studies (3,19,20) suggested that the present-day diversity of the arenaviruses is a product of long-term coevolution of the various viruses with their respective principal rodent hosts. In the present study, WWA viral strains AV 9310135 and AV 9310040 (both from N. albigula, northwestern New Mexico) appeared to be phylogenetically more closely related to strain AV 96010024 (N. mexicana, southeastern Utah) than to strains AV 98490013 and TVP-6038 (both from N. albigula, western Oklahoma). This situation suggests that the present-day association of WWA virus with N. albigula and N. mexicana does not represent a long-term shared evolutionary relationship between virus and rodent species. However, this conclusion assumes that recovery of WWA virus from a rodent represents a principal virus-host relationship. Perhaps some of the virus-positive rodents in the present study were infected by contact with other Neotoma species or even non-Neotoma rodent species. The geographic range of the genus Neotoma extends from western Canada south to Guatemala, Honduras, and Nicaragua, and includes 33 states in the contiguous United States and 26 of the 32 states in Mexico (21). Thus, if the present-day association of WWA virus with the genus Neotoma represents a long-term shared evolutionary relationship between virus and rodent host, the geographic range of the virus may extend far beyond the southwestern United States. WWA virus recently was associated with several human deaths in California (22). Further study is needed to assess the human health significance of this virus in the southwestern United States and other regions in North America in which woodrats are indigenous. Acknowledgments Robert Baker and Terry Yates provided the tissue specimens that were tested for infectious arenavirus; Wen Li Kang amplified and cloned the PCR products generated from isolates AV 96010149, AV 96010151, AV 96010025, and AV 96010024. This research was supported by the National Institutes of Health grant AI-41435 ("Ecology of emerging arenaviruses in the southwestern United States"). Dr. Fulhorst is assistant professor and member of the World Health Organization Collaborating Center for Tropical Diseases, University of Texas Medical Branch, Galveston. His research interests include the epidemiology of the arenaviruses, hantaviruses, and other viral zoonoses. References (1.) Southern PJ. 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Berlin: Springer-Verlag; 1973. p. 241-58. (21.) Musser GG, Carleton MD. Family Muridae. In: Wilson DE, Reeder DM, editors. Mammal species of the world. A taxonomic and geographic reference. Washington: Smithsonian Institution Press; 1993. p. 501-755. (22.) Centers for Disease Control and Prevention. Fatal illnesses associated with a New World arenavirus-California, 1999-2000. MMWR Morb Mortal Wkly Rep 2000;49:709-11. Charles F. Fulhorst,(*) Remi N. Charrel,(*)([dagger]) Scott C. Weaver,(*) Thomas G. Ksiazek,([double dagger]) Robert D. Bradley,([sections]) Mary L. Milazzo,(*) Robert B. Tesh,(*) and Michael D. Bowen([double dagger]) (*) University of Texas Medical Branch, Galveston, Texas, USA; ([dagger]) Faculte de Medecine, Marseille, France; Centers for Disease Control and Prevention, Atlanta, Georgia, USA; and ([sections]) Texas Tech University, Lubbock, Texas, USA Address for correspondence: Charles F. Fulhorst, Department of Pathology, Route 0609, University of Texas Medical Branch, Galveston, Texas 77555-0609, USA; fax: 409-747-2415; e-mail: cfulhors@utmb.edu |
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