Bringing up baby's DNA: less risky techniques for assessing fetal genes.At the age of 39, Robin Nolan of Carson City, Nev., found out that she was pregnant with her first child. The timing was perfect for her and her husband's personal and professional lives, but doctors warned Nolan that her age inflated the chance that her baby would have a congenital disease such as Down syndrome Down syndrome, congenital disorder characterized by mild to severe mental retardation, slow physical development, and characteristic physical features. Down syndrome affects about 1 in every 730 live births and occurs in all populations equally. . Three years later, Nolan has not only a perfectly normal son but also a healthy, 5-month-old daughter. Their well-being wasn't just a pleasant surprise. Like many older mothers, Nolan opted early in each pregnancy to have a procedure called amniocentesis amniocentesis (ăm'nēō'sĕntē`sĭs), diagnostic procedure in which a sample of the amniotic fluid surrounding a fetus is removed from the uterus by means of a fine needle inserted through the abdomen of the pregnant woman (see , in which a doctor uses a thin needle to draw fluid from the sac that surrounds a fetus. Fetal cells floating in this liquid hold a developing baby's 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. and so give doctors the means to get a precise readout (1) A small display device that typically shows only a few digits or a couple of lines of data. (2) Any display screen or panel. of genetic disorders that a fetus might have. Both amniocentesis and another procedure called chorionic villus sampling chorionic villus sampling (CVS) or chorionic villus biopsy (CVB) (kōr'ē-ŏn`ĭk, kôr'–), diagnostic procedure in which a sample of chorionic villi from the developing placenta is removed from the , in which doctors pluck bits of the placenta, isolate fetal cells that can reveal many genetic problems in an unborn baby with near certainty. But both procedures come with some risk because they invade the pregnant woman's uterus. Out of every 100 women who undergo these procedures, 1 or 2 will have a miscarriage. "I weighed the odds and thought it was more important to find out what was going on with my baby than whether I miscarried," says Nolan. Although the gamble paid off for Nolan, this risk isn't acceptable for some women. Researchers are developing new ways to harvest babies' genes in less risky ways--for example, from fetal DNA floating in a mother's blood or from cells that have detached from the placenta and lodged in her cervix. Scientists have a few hurdles to overcome before tests based on these techniques become routine, but safely learning about their baby's health in advance could put morns and dads a significant step ahead in preparing for parenthood. ROAMING FREE Amniocentesis and chorionic villus sampling are currently the only way doctors have for analyzing a fetus' genes, but scientists have for decades been contemplating how to replace these tests with less invasive ones. In the late 19th century, scientists found what looked like placental cells in the lungs of women who had died from preeclampsia preeclampsia /pre·eclamp·sia/ (pre?e-klamp´se-ah) a toxemia of late pregnancy, characterized by hypertension, proteinuria, and edema. pre·e·clamp·si·a n. , a condition that creates high blood pressure during pregnancy. In the 1970s, researchers identified the vehicle that delivers these cells to the lungs. It's a pregnant woman's blood. But they found that only about two to six fetal cells, such as immature red blood cells Red blood cells Cells that carry hemoglobin (the molecule that transports oxygen) and help remove wastes from tissues throughout the body. Mentioned in: Bone Marrow Transplantation red blood cells and immune cells, circulate in every milliliter milliliter /mil·li·li·ter/ (mL) (-le?ter) one thousandth (10-3) of a liter. mil·li·li·ter n. Abbr. of maternal blood. Prenatal-genetics researcher Diana W. Bianchi of Tufts University in Boston made one of the earliest attempts to harvest these cells. Using an antibody that binds to a protein found mostly on the surface of fetal cells, Bianchi and her colleagues showed in 1990 that they could pluck out a few of the precious cells floating in samples of a pregnant woman's blood. But since these cells are so rare--virtually undetectable in some women--and tricky to distinguish from a mother's own cells, Bianchi and other researchers put these circulating cells on the back burner as a new source for genetic testing Genetic Testing Definition A genetic test examines the genetic information contained inside a person's cells, called DNA, to determine if that person has or will develop a certain disease or could pass a disease to his or her offspring. . A major advance came in 1998 when Dennis Lo, now at the Chinese University of Hong Kong The motto of the university is "博文約禮" in Chinese, meaning "to broaden one's intellectual horizon and keep within the bounds of propriety". , and his colleagues reported that fetal DNA circulates freely outside of cells in a pregnant woman's bloodstream. Lo notes that this genetic material seems to make its way into maternal blood when placental cells die, rupture, and spill their contents into the mother's bloodstream. Studies have since shown that about 20,000 placental cells die per minute under normal conditions. Even more DNA enters the mother's bloodstream when she or the fetus has certain health problems, such as preeclampsia or Down syndrome. Lo notes that circulating fetal DNA sticks around for several minutes in a mother's blood, providing ample time for researchers to harvest the genetic material for prenatal tests. The tricky part, he adds, is separating the baby's DNA from maternal DNA that also floats in the bloodstream. "It's easy if the baby is a boy--then you can just use the Y-chromosome as a marker," says Lo. To make the tests usable for girls, he adds, "we need to find something else that's fetal specific." In the Oct. 11, 2005 Proceedings of the National Academy of sciences The Proceedings of the National Academy of Sciences of the United States of America, usually referred to as PNAS, is the official journal of the United States National Academy of Sciences. , Lo and his team reported on a novel way to differentiate a baby's DNA from its mother's. The accomplishment took advantage of a phenomenon called epigenetics, in which chemical modifiers, such as methyl groups, attach directly to DNA and regulate gene activity (SN: 6/24/06, p. 392). Since epigenetic epigenetic /epi·ge·net·ic/ (-je-net´ik) 1. pertaining to epigenesis. 2. altering the activity of genes without changing their structure. modifications can change with a person's age, Lo and his team wondered whether they could find some genes that are methylated meth·yl·ate n. An organic compound in which the hydrogen of the hydroxyl group of methyl alcohol is replaced by a metal. tr.v. meth·yl·at·ed, meth·yl·at·ing, meth·yl·ates 1. differently in a fetus than in its mother. After searching through thousands of candidates, the researchers focused on Maspin, a tumor-suppressing gene that's active in the fetal cells of a placenta but not typically in a mother's cells. Lo and his colleagues found that the gene is usually methylated in a mother's blood but unmethylated in the placenta. In subsequent tests, the researchers found that they could detect fetal DNA with unmethylated Maspin in all three trimesters of pregnancy. Using their new technique to reveal excessive fetal DNA in some mothers' bloodstreams, the researchers reliably predicted which women would develop preeclampsia. The team plans on looking for Looking for In the context of general equities, this describing a buy interest in which a dealer is asked to offer stock, often involving a capital commitment. Antithesis of in touch with. epigenetic markers that might disclose the presence of specific diseases of the fetus, such as Down syndrome. That disease is marked by three copies of chromosome 21, but the phenomenon can currently be detected only by examining whole fetal cells. Recently, a team of scientists led by molecular biologist Sinuhe Hahn of University Hospital in Basel, Switzerland, discovered another way to reliably separate fetal DNA from maternal genetic material. The researchers made the chance discovery that circulating bits of a baby's genetic material are significantly shorter than a mother's. Though the researchers aren't sure why that is, one idea is that the high rate of turnover among placental cells might shatter long strings of DNA into strands much shorter than those of maternal origin. In the Feb. 16, 2005 Journal of the American Medical Association JAMA: The Journal of the American Medical Association is an international peer-reviewed general medical journal, published 48 times per year by the American Medical Association. JAMA is the most widely circulated medical journal in the world. , Hahn's team showed that separating circulating DNA on the basis of size could provide a new way to test for genetic disease in a fetus. The researchers took blood samples from 32 pregnant women carrying fetuses at high risk of beta-tha-lassemia, a genetic disease that causes severe anemia. The scientists separated the circulating strands into short and long strands and then tested the batch of shorter strands for four mutations known to cause the disease. Checking their findings against chorionic villus sampling, the researchers identified the mutations in the circulating fetal DNA with almost 100 percent accuracy. Hahn and his team are currently working to expand their findings into tests for other genetic conditions. CELL SOLUTION Although much of the work on new prenatal tests now focuses on circulating fetal DNA, some scientists still see plenty of promise in the whole fetal cells found in maternal blood and elsewhere. If researchers find a reliable way to isolate enough fetal cells, they could be more useful than circulating fetal DNA, says cell biologist Esther Guetta of Chaim Sheba Medical Center in Tel-Hashomer, Israel. For example, for a recessive recessive /re·ces·sive/ (re-ses´iv) 1. tending to recede; in genetics, incapable of expression unless the responsible allele is carried by both members of a pair of homologous chromosomes. 2. disease such as sickle cell anemia sickle cell anemia n. A chronic, usually fatal inherited form of anemia marked by crescent-shaped red blood cells, occurring almost exclusively in Blacks, and characterized by fever, leg ulcers, jaundice, and episodic pain in the joints. , in which two copies of a problem gene are packed in each cell, it's difficult to distinguish whether a copy circulating in the blood belongs to the fetus or the mother. That wouldn't pose a problem if researchers had whole fetal cells to work with, Guetta notes. "If you have the whole cell, then you know that all the fetus' DNA is compartmentalized com·part·men·tal·ize tr.v. com·part·men·tal·ized, com·part·men·tal·iz·ing, com·part·men·tal·iz·es To separate into distinct parts, categories, or compartments: "You learn . . . in that cell," Guetta says. "[Cell free] DNA is important, but it won't answer all the questions." She and other researchers have identified several different types of fetal cells, such as immature red blood cells and stem cells stem cells, unspecialized human or animal cells that can produce mature specialized body cells and at the same time replicate themselves. Embryonic stem cells are derived from a blastocyst (the blastula typical of placental mammals; see embryo), which is very young , that circulate along with placental cells in a mother's bloodstream. Her team is tackling the problem of fetal cells' rarity in maternal blood by developing methods to grow those cells into easy-to-test colonies in the lab. In the March 2005 Journal of Histochemistry histochemistry /his·to·chem·is·try/ (his?to-kem´is-tre) that branch of histology dealing with the identification of chemical components in cells and tissues.histochem´ical his·to·chem·is·try n. and Cytochemistry cytochemistry /cy·to·chem·is·try/ (-kem´is-tre) the identification and localization of the different chemical compounds and their activities within the cell. cy·to·chem·is·try n. , Guetta and her colleagues showed for the first time that circulating placental cells could multiply in the lab. Starting with blood samples that held only one or two fetal cells per 20 ml of blood, the researchers placed the cells in a specially crafted mixture of nutrients and proteins to increase this number about five-fold over the course of 5 to 7 days. Guetta's team used these new cells to predict a fetus' gender with about 93 percent accuracy. Joe Leigh Simpson of Baylor College of Medicine Baylor College of Medicine is a private medical school located in Houston, Texas, USA on the grounds of the Texas Medical Center. It has been consistently rated the top medical school in Texas and among the best in the United States. in Houston and his colleagues are currently investigating how to make use of another promising source of fetal cells: the mucus plug that fills a pregnant woman's cervix. Besides shedding cells into the bloodstream, the placenta deposits cells into this mucus plug, notes Simpson. "The attraction is that there are lots of cells there," he says. Having such cells harvested would be "like having a Pap smear Pap smear or Papanicolaou smear Sample of cells from the vagina and cervix of the uterus for laboratory staining and examination to detect genital herpes and early-stage cancer, especially of the cervix. Developed by the Greek-born U.S. ," he adds, referring to the simple procedure that many women have once a year to check for cervical cancer Cervical Cancer Definition Cervical cancer is a disease in which the cells of the cervix become abnormal and start to grow uncontrollably, forming tumors. and other health problems. However, Simpson notes that several challenges must be overcome before harvesting cells from the mucus plug is practical for prenatal testing Prenatal testing Testing for a disease such as a genetic condition in an unborn baby. Mentioned in: Retinoblastoma, Von Willebrand Disease . For example, it isn't easy to extract the fetal cells from the thick, sticky mucus--researchers need to identify chemicals that dissolve this type of mucus without killing the cells. Also, since many maternal cells are mixed in with the fetal cells, researchers must come up with a way to distinguish a baby's cells from its mother's. Working with a company called Biocept in San Diego, Simpson and other researchers are testing several promising solutions to these problems. BUNDLE OF QUESTIONS As scientists move closer to developing genetic tests that match the reliability of amniocentesis and chorionic villus sampling but lessen their potential harm to a fetus, some researchers expect that more women will choose to undergo prenatal testing. That's likely to raise the possibility that more mothers will hear that their unborn baby has a worrisome genetic condition, says Brian Skotko, a Harvard researcher who specializes in medicine and public policy. "It's not inconceivable that in the future, a woman will be able to get a preganancy test and at the same time find out if her baby has Down syndrome or another disability," he says. "It definitely opens a new avenue in the [obstetrics and gynecology obstetrics and gynecology Medical and surgical specialty concerned with the management of pregnancy and childbirth and with the health of the female reproductive system. ] world with ethical and personal questions." One of those questions that Skotko recently investigated was how doctors should tell a mother that she is carrying a child with Down syndrome, which currently affects about 350,000 people in the United States. In the January 2005 Pediatrics and the March 2005 American Journal of Obstetrics and Gynecology, Skotko published two studies that concluded that doctors often tell mothers about their baby's diagnosis in an overwhelmingly negative way, using insensitive language and focusing on the hardships and limitations that their child may face. Doctors also frequently assume that a woman carrying a child with Down syndrome will want to terminate her pregnancy. Nowadays, that's often not the case, says Skotko. Medical advances and society's changing perceptions have greatly improved the quality of life for people with Down syndrome and many other congenital conditions--and for their parents. Nevertheless, if tests can safely spot a fetus' genetic problems, more parents will have a chance to plan for their family's future, whatever they choose. Says Skotko: "More parents will eventually need to decide, 'Is this life valuable?' It's a tantalizing tan·ta·lize tr.v. tan·ta·lized, tan·ta·liz·ing, tan·ta·liz·es To excite (another) by exposing something desirable while keeping it out of reach. question that's a profoundly personal one." |
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