Four geographically distinct genotypes of JC virus are prevalent in China and Mongolia: implications for the racial composition of modern China

Viruria of Human BK Virus and John Cunningham Virus among Renal Transplant Recipients and Healthy Control in Southeast of Caspian Sea

BACKGROUND

Members of the Polyomaviridae family, BK virus (BKV), and John Cunningham virus (JCV) are linked to polyomavirus-associated nephropathy-associated transplant rejection in immunodeficient patients.

OBJECTIVE

The aim of the study was to evaluate the prevalence of BKV and JCV in immunocompetent individuals in the north of Iran.

METHODS

Ninety-one urine samples were obtained from renal transplant recipients with a mean age of 39.78 ± 11.19 years. A healthy control group of 65 volunteers with an average age of 40.32 ± 10.7 years also contributed. After DNA extraction, positive cases were detected through PCR. Genotyping was done by alignment and phylogenetic tree construction of the VP1 region against all known JCV and BKV genotypes.

RESULTS

The prevalence of BKV and JCV was 15.38 and 19.78%, respectively. JCV was detected in 7.69% of the control group. The prevalence of the BKV between the case and control groups was significant (p < 0.0001). There was no significant association between BKV and JCV and duration of dialysis (p > 0.05). Overall, 62.16% of JCV cases were genotype I. Besides, genotype II was dominant within patients with BKV-positive patients.

DISCUSSION

The results obtained here show a relatively lower prevalence of BKV and JCV in immunocompromised renal transplant receivers and healthy control than those reported from other areas in Iran. JCV genotyping was evaluated for the first time in Iran. Genotype I for JCV and genotype II for BKV were dominant genotypes in the north of Iran.

Prevalence, reactivation and genotyping of John Cunningham virus among end-stage renal disease and kidney transplant patients

Aim: Infection of John Cunningham virus (JCV) usually occurs in early childhood and can lead to progressive multifocal leukoencephalopathy in immunosuppressed individuals. In this study, prevalence, reactivation and genotypes of JCV were evaluated. Materials & methods: Overall, 128 sex-matched individuals, including 64 patients with end-stage renal disease (ESRD) and 64 kidney transplant (KT) patients were evaluated using PCR and reverse transcriptase-PCR. Results: JCV DNA was detected in the urine samples of 17.2% of KT recipients and 1.6% of ESRD patients. Reactivation of JCV was determined in 12.5% of KT patients. All JCV-DNA-positive samples belonged to Af2 genotype (subtype b). Conclusion: Rare excretion of JCV in the ESRD urine samples can be associated with kidney function. JCV shedding and reactivation occur more frequently in the first 2 years following kidney transplantation. The genotype of Af2-b is circulating among the population of Iran.

Tracing Jomon and Yayoi ancestries in Japan using ALDH2 and JC virus genotype distributions

BACKGROUND

According to the dual structure model, the modern Japanese ethnic population consists of a mixture of the Jomon people, who have existed in Japan since at least the New Stone Age, and the Yayoi people, who migrated to western Japan from China around the year 300 bc Some reports show that the Yayoi are linked to a mutation of the aldehyde dehydrogenase 2 gene (ALDH2). Recent viral studies indicate two major groups found in the Japanese population: a group with the CY genotype JC virus (JCV) and a group with the MY genotype JCV. It is unclear whether either genotype of the JC virus is related to the Jomon or Yayoi. In this study, we attempted to detect JCV genotypes and ALDH2 mutations from the DNA of 247 Japanese urine samples to clarify the relationship between the dual structure model and the JCV genotype through ALDH2 mutation analysis and JCV genotyping.

FINDINGS

The ALDH2 polymorphism among 66 JC virus-positive samples was analyzed, and it was found that the ALDH2 variant is significantly higher in the population with CY genotype JCV (51.5 %) than in the population with the MY genotype (24.2 %) (p < 0.05).

CONCLUSION

From these findings, it may be inferred that the ALDH2 mutation, which is related to the Yayoi, is related to CY genotype JCV. When the Yayoi migrated to the Japanese archipelago, they brought the ALDH2 mutation as well as the CY genotype JCV.

Distribution of JC polyomavirus genotypes in Tunisian renal transplant recipients between January 2008 and January 2011

The polyomavirus JC (JCPyV) is a ubiquitous virus in humans, causing progressive multifocal leukoencephalopathy, a fatal demyelinating disease. JCPyV propagates in the adult kidney and excretes its progeny in urine, from which its DNA can be recovered readily. JCPyV isolates worldwide can be classified into 14 subtypes or genotypes, each associated with a specific geographical region. The European genotypes EU-a-b-c are spread throughout Europe and Mediterranean areas. The major African genotype Af2 is spread not only throughout Africa but also in West and South Asia. A minor African genotype (Af1) occurs in Central and West Africa. Partially overlapping domains in Asia were occupied by various genotypes (e.g., B1-a, -b, -d, B2, CY, MY, and SC). To characterize the subtypes of JCPyV prevalent in Tunisia, the presence of the virus was investigated by real-time PCR in urine samples from 98 renal transplant recipients. For subtype identification, a 610 bp typing region of the JCPyV genome was amplified from each urine sample, and its DNA sequence was determined. In the patients studied, the major African subtype Af2 was the predominant (62.5%), followed by the European subtype EU (33.5%). Only one case clustering with the Asian genotype SC (4%) was identified. The presence of the European subtype with high prevalence in this population suggests that the epidemiological distribution of JCPyV virus sequences in North Africa is related partially to the epidemiological data in Europe.

Genetic variability and integration of Merkel cell polyomavirus in Merkel cell carcinoma

Merkel cell polyomavirus (MCPyV) is associated to Merkel cell carcinoma (MCC). We studied 113 MCC tumoral skin lesions originating from 97 patients. MCPyV detection was higher in fresh-frozen (FF) biopsies (94%) than in formalin-fixed paraffin-embedded biopsies (39-47%). Mean viral load in FF tumor was of 7.5 copies per cell with a very wide range (0.01-95.4). Nineteen complete sequences of LTAg were obtained, mainly from FF biopsies when the viral load was high. Seventeen showed stop codons, all localized downstream of the pRb protein binding domain. Sequence comparison and phylogenetic analysis showed that all sequences clustered in the large C clade of MCPyV strains. MCPyV integration was demonstrated in 19 out of 27 FF MCC DNA biopsies without evidence of specific host cellular genome integration site. In 13/19 cases, the viral junction was located within the second exon of the LTAg, after the pRB binding domain.

Discovery and epidemiology of the human polyomaviruses BK virus (BKV) and JC virus (JCV)

Although discovered over thirty years ago, many aspects of the epidemiology of BKV and JCV in the general population, such as the source of infectious virus and the mode of transmission, are still unknown. Primary infection with both BKV and JCV is usually asymptomatic, and so age seroprevalence studies have been used to indicate infection. BKV commonly infects young children in all parts of the world, with the exception of a few very isolated communities, adult seroprevalence rates of 65-90% being reached by the age of ten years. In contrast, the pattern of JCV infection appears to vary between populations; in some anti-JCV antibody is acquired early as for BKV, but in others anti-JCV antibody prevalence continues to rise throughout life. This indicates that the two viruses are probably transmitted independently and by different routes. Whilst BKV DNA is found infrequently in the urine of healthy adults, JCV viruria occurs universally, increasing with age, with adult prevalence rates often between 20% and 60%. Four antigenic subtypes have been described for BKV and eight genotypes are currently recognized for JCV. The latter have been used to trace population movements and to reconstruct the population history in various communities.

Phylogenetic analysis of major African genotype (Af2) of JC virus: Implications for origin and dispersals of modern Africans

Both mtDNA and the Y chromosome have been used to investigate how modern humans dispersed within and out of Africa. This issue can also be studied using the JC virus (JCV) genotype, a novel marker with which to trace human migrations. Africa is mainly occupied by two genotypes of JCV, designated Af1 and Af2. Af1 is localized to central/western Africa, while Af2 is spread throughout Africa and in neighboring areas of Asia and Europe. It was recently suggested that Af1 represents the ancestral type of JCV, which agrees with the African origin of modern humans. To better understand the origin of modern Africans, we examined the phylogenetic relationships among Af2 isolates worldwide. A neighbor-joining phylogenetic tree was constructed based on the complete JCV DNA sequences of 51 Af2 isolates from Africa and neighboring areas. According to the resultant tree, Af2 isolates diverged into two major clusters, designated Af2-a and -b, with high bootstrap probabilities. Af2-a contained isolates mainly from South Africa, while Af2-b contained those from the other parts of Africa and neighboring regions of Asia and Europe. These findings suggest that Af2-carrying Africans diverged into two groups, one carrying Af2-a and the other carrying Af2-b; and that the former moved to southern Africa, while the latter dispersed throughout Africa and to neighboring regions of Asia and Europe. The present findings are discussed with reference to relevant findings in genetic and linguistic studies.

Deciphering host migrations and origins by means of their microbes

Mitochondrial DNA and microsatellite sequences are powerful genetic markers for inferring the genealogy and the population genetic structure of animals but they have only limited resolution for organisms that display low genetic variability due to recent strong bottlenecks. An alternative source of data for deciphering migrations and origins in genetically uniform hosts can be provided by some of their microbes, if their evolutionary history correlates closely with that of the host. In this review, we first discuss how a variety of viruses, and the bacterium Helicobacter pylori, can be used as genetic tracers for one of the most intensively studied species, Homo sapiens. Then, we review statistical problems and limitations that affect the calculation of particular population genetic parameters for these microbes, such as mutation rates, with particular emphasis on the effects of recombination, selection and mode of transmission. Finally, we extend the discussion to other host-parasite systems and advocate the adoption of an integrative approach to both sampling and analysis.

Genetic diversity of JC virus in the Saami and the Finns: implications for their population history

The JC virus (JCV) genotyping method was used to gain insights into the population history of the Saami and the Finns, both speaking Finno-Ugric languages and living in close geographic proximity. Urine samples from Saami and Finns, collected in northern and southern Finland, respectively, were used to amplify a 610-bp JCV-DNA region containing abundant type-specific mutations. Based on restriction site polymorphisms in the amplified fragments, we classified JCV isolates into one of the three superclusters of JCV, type A, B, or C. All 15 Saami isolates analyzed and 41 of 43 Finnish isolates analyzed were classified as type A, the European type, and two samples from Finns were classified as type B, the African/Asian type. We then amplified and sequenced a 583-bp JCV-DNA region from the type A isolates of Saami and Finns. According to type-determining nucleotides within the region, we classified type A isolates into EU-a1, -a2, or -b. Most type A isolates from Saami were classified as EU-a1, while type A isolates from Finns were distributed among EU-a1, EU-a2, and EU-b. This trend in the JCV-genotype distribution was statistically significant. On a phylogenetic tree based on complete sequences, most of the type A isolates from Saami were clustered in a single clade within EU-a1, while those from Finns were distributed throughout EU-a1, EU-a2, and EU-b. These findings are discussed in the context of the population history of the Saami and the Finns. This study provides new complete JCV DNA sequences derived from populations of anthropological interest.

Genotypes of JC virus, DNA of cytomegalovirus, and proviral DNA of human immunodeficiency virus in eyes of acquired immunodeficiency syndrome patients

JC virus (JCV) is a human polyomavirus that exists in at least eight different genotypes as a result of coevolution with different human populations all over the world. Well adapted to its host, it usually persists in the kidneys and possibly the brain. If the host becomes immunodeficient, JCV can cause the fatal demyelinating disease progressive multifocal leukoencephalopathy (PML). There is increasing evidence that JCV is transactivated by cytomegalovirus (CMV) and the human immunodeficiency virus (HIV). Both CMV and HIV can infect the retina of acquired immunodeficiency syndrome (AIDS) patients, causing severe necrosis in the case of CMV retinitis or a mild HIV-associated vasculopathy, with bleeding and cotton wool spots. The authors therefore investigated by polymerase chain reaction (PCR) whether DNA of these three viruses was detectable in paraffin-embedded eyes of AIDS patients with a clinical history of CMV retinitis. From a total of 65 eyes, JCV was detected in 21 (32%). Thirty-six (55%) were positive for CMV and 6 (9%) for proviral DNA of HIV. JCV and CMV were found in 13 eyes, JCV and HIV in 3 eyes, CMV and HIV in 1 eye, and DNA from all three viruses in 1 eye. The JCV genotypes were types 1A, 2A, 2E, 3, and 4. In 21 eyes of patients without AIDS, only one sample was JCV positive. In conclusion, JCV DNA can be detected in ocular tissue of AIDS patients at a significantly higher level than in eyes of nonimmunosuppressed patients. Further investigations will help to decide if JCV contributes to the retinopathy caused by CMV and HIV.

Analysis of 15 novel full-length BK virus sequences from three individuals: evidence of a high intra-strain genetic diversity

To determine the variability of BK virus (BKV) in vivo, the sequences of nine full-length molecular clones from the striated muscle and heart DNA of a patient with BKV-associated capillary leak syndrome (BKVCAP), as well as three clones each from the urine of one human immunodeficiency virus type 2-positive (BKVHI) and one healthy control subject (BKVHC), were analysed. The regulatory region of all clones corresponded to the archetypal regulatory region usually found in urine isolates. Analysis of the predicted conformation of BKVCAP proteins did not suggest any structural differences on the surface of the viral particles compared with BKVHI and BKVHC clones. No amino acid changes common to most BKVCAP clones could be identified that have not already been reported in non-vasculotropic strains. However, the coding region of each clone had unique nucleotide substitutions, and intra-host variability was greater among BKVCAP clones, with a mean difference of 0.29 % per site compared with 0.16 % for BKVHI and 0.14 % for BKVHC. The clones from each strain formed monophyletic clades, suggesting a single source of infection for each subject. The most divergent BKVCAP clones differed at 0.55 % of sites, implying a rate of nucleotide substitution of approximately 5 x 10(-5) substitutions per site per year, which is two orders of magnitude faster than estimated for the other human polyomavirus, JC virus.

Regional distribution of two related Northeast Asian genotypes of JC virus, CY-a and -b: implications for the dispersal of Northeast Asians

JC virus (JCV) is a useful marker to trace human dispersal. Two genotypes of JCV (MY and CY) are mainly distributed in Northeast Asia. The population history of people carrying MY has been studied in some detail but that of people carrying CY remains poorly understood. To gain insights into the population history of Northeast Asians carrying CY we analyzed the genetic variation in CY isolates. We constructed a neighbor-joining phylogenetic tree from 28 complete CY DNA sequences: on the resultant tree the CY DNA sequences diverged into two clades, designated CY-a and -b, each clustered with a high bootstrap probability. The split into CY-a and -b was estimated to have occurred about 10 000 years ago, based on K(s) values (synonymous substitutions per synonymous site) and the suggested rate of synonymous nucleotide substitutions. Comparison of the 28 complete CY sequences revealed six nucleotide mismatches between CY-a and -b, one of which showed a restriction fragment length polymorphism (RFLP). We then PCR-amplified a region of the genome containing this polymorphic site from many CY isolates in various Northeast Asian populations and classified the isolates into CY-a or -b according to the RFLP analysis. CY-a was more abundant than CY-b in various Chinese and Japanese populations but CY-b was more abundant than CY-a in South Koreans. On the basis of the present findings we inferred the population history in East Asians carrying CY.

Distinguishing human ethnic groups by means of sequences from Helicobacter pylori: lessons from Ladakh

The history of mankind remains one of the most challenging fields of study. However, the emergence of anatomically modern humans has been so recent that only a few genetically informative polymorphisms have accumulated. Here, we show that DNA sequences from Helicobacter pylori, a bacterium that colonizes the stomachs of most humans and is usually transmitted within families, can distinguish between closely related human populations and are superior in this respect to classical human genetic markers. H. pylori from Buddhists and Muslims, the two major ethnic communities in Ladakh (India), differ in their population-genetic structure. Moreover, the prokaryotic diversity is consistent with the Buddhists having arisen from an introgression of Tibetan speakers into an ancient Ladakhi population. H. pylori from Muslims contain a much stronger ancestral Ladakhi component, except for several isolates with an Indo-European signature, probably reflecting genetic flux from the Near East. These signatures in H. pylori sequences are congruent with the recent history of population movements in Ladakh, whereas similar signatures in human microsatellites or mtDNA were only marginally significant. H. pylori sequence analysis has the potential to become an important tool for unraveling short-term genetic changes in human populations.

Genetic diversity of JC virus in the modern Filipino population: implications for the peopling of the Philippines

The Philippines is generally believed to have been established by various peoples who migrated from neighboring areas. To gain new insights into the peopling of the Philippines, we used the JC virus (JCV) genotyping approach. We collected about 50 urine samples on each of two representative islands of the Philippines, Luzon and Cebu. DNA was extracted from the urine samples and used to amplify the 610-bp region (IG region) of the viral genome. For each island, we determined about 20 IG sequences, from which a neighbor-joining phylogenetic tree was constructed to classify the JCV isolates detected into distinct genotypes. The predominant genotype detected was SC, the Southeast Asian genotype. Minor JCV genotypes were SC/Phi, B1-a, and B3. SC/Phi was a subcluster of SC and has not been detected in areas other than the Philippines. B1-a was detected previously in mainland China, Pamalican Island (Palawan, Philippines), and Taiwan (an aboriginal tribe). B3 was classified in this study into two subgroups, one (B3-a) containing three Luzon isolates and several Chinese, Thai, and Uzbek isolates, the other (B3-b) containing two Luzon, one Cebu, and one Indonesian isolate. These findings suggest that the modern Filipino population was formed not only by Southeast Asians carrying SC but also by a few distinct ethnic groups carrying SC/Phi, B1-a, and B3-a or -b.

Genotyping of the JC virus in urine samples of healthy Korean individuals

A human polyomavirus, JC virus (JCV) is ubiquitous in humans and infects children asymptomatically. It persists in renal tissue and is excreted progeny in urine. DNAs from urine samples of 100 healthy Korean individuals were screened for the presence of JCV by polymerase chain reaction (PCR). Twenty of the samples were positive for JCV. JCV DNA was found in one individual (4%) in the 1-19-year group, two individuals (9%) in the 20-39-year group, ten individuals (38%) in the 40-59-year group, seven individuals (28%) in the over 60-year group. The prevalence of JC viral DNA was the highest in the 40-59-year-old Korean population. To investigate genotypes of JCV in Korea, the genotypes were determined by DNA sequence analysis of the regulatory region (333 bp) and the VT-intergenic region (656 bp) of DNA from the 20 JCV isolates. We have identified three distinctive JCV strains in the regulatory region and ten distinctive JCV strains in the VT-intergenic region of DNA from the 20 isolates. Based on restriction fragment length polymorphism (RFLP) analysis and phylogenetic analysis of the VT-intergenic region of JCV, two distinct subtypes, CY and type 2A (MY), were found to be prevalent in this Korean population. CY and type 2A of JCV were identified in 13 individuals (65%) and four individuals (20%), respectively. Interestingly, type 1, which was distributed mostly in Europe, was found in 3 (15%) isolates from healthy Korean individuals.

Asian genotypes of JC virus in Japanese-Americans suggest familial transmission

To examine the mode of JC virus (JCV) transmission, we collected urine samples from second- and third-generation Japanese-Americans in Los Angeles, Calif., whose parents and grandparents were all Japanese. From the urine samples of these Japanese-Americans, we mainly detected two subtypes (CY and MY) of JCV that are predominantly found among native Japanese. This finding provides support for the hypothesis that JCV is transmitted mainly within the family through long-term cohabitation.

Strains of JC virus in Amerind-speakers of North America (Salish) and South America (Guaraní), Na-Dene-speakers of New Mexico (Navajo), and modern Japanese suggest links through an ancestral Asian population

Previously we showed that strains of human polyoma virus JC among the Navajo in New Mexico, speakers of an Athapaskan language in the Na-Dene language phylum, and among the Salish people in Montana, speakers of a language of the Salishan group in the Amerind family, were mainly of a northeast Asian genotype found in Japan (type 2A). We now report partial VP1-gene, regulatory region, and complete genome sequences of JC virus (JCV) from the Guaraní Indians of Argentina. The Tupí-Guaraní language represents the Equatorial branch of the Amerind language family proposed by Greenberg ([1987] Language in the Americas, Stanford: Stanford University Press). The partial VP1 gene sequences of the Guaraní revealed several variants of strains found in northeast Asia (Japan), as did the Salish. In contrast, the strains in the Navajo largely conformed to the prototype type 2A sequence (MY). Phylogenetic reconstruction with both the neighbor-joining and maximum parsimony methods utilized three complete Guaraní JCV genome sequences, three genomes from the Salish people, and 27 other complete JCV genomes, including three from the Navajo and three from Japan. Both trees showed that all type 2A JCV strains from the North and South Americans are closely related phylogenetically to strains in present-day Japan. However, variant sites in the coding regions, the T-antigen intron, and the regulatory region link the type 2A strains in Amerind groups (Guaraní and Salish), but differentiate them from those in a Na-Dene-speaking (Navajo) population. The data suggest separation from a population ancestral to modern Japanese, followed by a second division within the ancestral group that led to Amerind- and Na-Dene-speaking groups. The data cannot, however, localize the latter split to the Asian mainland (two migrations) or to North America (one migration).

High prevalence of TT virus-related DNA (90%) and diverse viral genotypes in Norwegian blood donors

Early estimates of the prevalence of TTV viremia in healthy adults of developed countries were in the order of 1--10 %, while similar estimates in Third World countries were considerably higher. Using three different PCRs, TTV-related DNA was detected in serum from 180 out of the 201 Norwegian blood donors tested, indicating that these viruses are almost universally present in adults. Sequence analysis revealed heterogeneity similar to what is found world-wide. The data suggest that the previous discrepancy in prevalences might be related to a lower serum concentration of virus in developed countries. The high prevalence adds evidence to the benign nature of the virus.

Do human and JC virus genes show evidence of host-parasite codemography?

Information about similarities and differences in the demographic history of host and parasite populations is potentially useful for making inferences about a variety of evolutionary processes. However, it is difficult to observe the historical demographic properties of natural populations directly. Here, the extent of demographic similarity in a host and its parasite was examined indirectly by inferring long-term population history from patterns of genetic variation. Nucleotide sequence diversity in human and JC virus (JCV) DNA is consistent with a long-term demographic connection between the two species: both show evidence of large-scale population expansion. However, genetic data also suggest that the two species have different patterns of population substructuring. These similarities and differences have implications for adaptive evolution in JCV that are not evident when the two species are considered separately.

Natural biology of polyomavirus middle T antigen

"It has been commented by someone that 'polyoma' is an adjective composed of a prefix and suffix, with no root between--a meatless linguistic sandwich" (C. J. Dawe). The very name "polyomavirus" is a vague mantel: a name given before our understanding of these viral agents was clear but implying a clear tumor life-style, as noted by the late C. J. Dawe. However, polyomavirus are not by nature tumor-inducing agents. Since it is the purpose of this review to consider the natural function of middle T antigen (MT), encoded by one of the seemingly crucial transforming genes of polyomavirus, we will reconsider and redefine the virus and its MT gene in the context of its natural biology and function. This review was motivated by our recent in vivo analysis of MT function. Using intranasal inoculation of adult SCID mice, we have shown that polyomavirus can replicate with an MT lacking all functions associated with transformation to similar levels to wild-type virus. These observations, along with an almost indistinguishable replication of all MT mutants with respect to wild-type viruses in adult competent mice, illustrate that MT can have a play subtle role in acute replication and persistence. The most notable effect of MT mutants was in infections of newborns, indicating that polyomavirus may be highly adapted to replication in newborn lungs. It is from this context that our current understanding of this well-studied virus and gene is presented.

Genotypes of JC virus in East, Central and Southwest Europe

Distinctive genotypes of JC virus have been described for the major continental landmasses. Studies on European-Americans and small cohorts in Europe showed predominantly Type 1. Types 2 and 7 are found in Asia, and Types 3 and 6 in Africa. These genotypes differ in sequence by about 1--3%. Each genotype may have several subtypes which differ from each other by about 0.5--1%. The genotypes can be defined by a distinctive pattern of nucleotides in a typing region of the VP1 gene. This genotyping approach has been confirmed by phylogenetic reconstruction using the entire genome exclusive of the rearranging regulatory region. In this first large European study, we report on the urinary excretion of JCV DNA of 350 individuals from Poland, Hungary, Germany and Spain. We included Gypsy cohorts in Hungary (Roma), Germany (Sinti), and Spain (Gitano), as well as Basques in Spain. We show that while Type 1 predominates in Europe, the proportions of Type 1A and 1B may differ from East to Southwest Europe. Type 4, closely related to the Type 1 sequence (only approximately 1% difference) was a minor genotype in Germany, Poland and Spain, but represented the majority in Basques. The Gitanos in Spain showed a variant Type 4 sequence termed 'Rom-1'. Interestingly, neither the Gitanos in Spain, nor Sinti or Roma in Germany or Hungary showed the Type 2 or Type 7 genotype that might be expected if their origins were in an Asian population.

Population structure and history in East Asia

Archaeological, anatomical, linguistic, and genetic data have suggested that there is an old and significant boundary between the populations of north and south China. We use three human genetic marker systems and one human-carried virus to examine the north/south distinction. We find no support for a major north/south division in these markers; rather, the marker patterns suggest simple isolation by distance.

JC virus as a marker of human migration to the Americas

JC virus is a ubiquitous human polyomavirus present in populations worldwide. Seven genotypes differing in DNA sequence by approximately 1-3% characterize three Old World population groups (African, European and Asian) as well as Oceania. It is possible to follow Old World populations into the New World by the JC virus genotypes they carried. The first population to settle in the Americas, the Native Americans, brought with them type 2A from northeast Asia. European settlers arriving after Columbus carried primarily type 1 and type 4. Africans brought by the slave trade carried type 3 and type 6.

VP1 DNA sequences of JC and BK viruses detected in urine of systemic lupus erythematosus patients reveal no differences from strains expressed in normal individuals

The ubiquitous human polyomaviruses BK (BKV) and JC (JCV) persist with no adverse effects in immunocompetent individuals. Virus-induced pathogenesis has been linked to virus reactivation during impaired immune conditions. Previous studies have shown a significant difference between the VP1 DNA sequences of JCV obtained from control urine samples and those in progressive multifocal leukoencephalopathy brain samples. This difference could not be detected when comparing normal control urinary JCV DNA with DNA sequences from chronic progressive multiple sclerosis patients. Since BKV and JCV are readily activated in systemic lupus erythematosus (SLE) patients, the presence of specific strains, related to VP1 DNA sequences, was investigated in these patients. VP1 DNA sequences in 100 urine samples from 21 SLE patients and 75 urine samples from 75 healthy pregnant women were analysed and compared to previously reported sequences. The results show that the VP1 sequence profiles of JCV and BKV excreted by SLE patients do not differ significantly from those excreted by immunocompetent individuals. The European JCV subtypes 1A or 1B were represented among all JCV-positive urine specimens, while BKV VP1 sequences showed complete, or almost complete, identity with the MM or JL strains. Different urine samples from the same patient collected over a 1 year period were predominantly stable. BKV VP1 DNA in urine specimens from healthy pregnant women was only detected during the third trimester of their pregnancy. These results argue against SLE-specific JCV and BKV strains and suggest reactivation of the viruses rather than recurrent re-infections of patients with SLE.

Human polyomavirus JC variants in Papua New Guinea and Guam reflect ancient population settlement and viral evolution

The peopling of the Pacific was a complex sequence of events that is best reconstructed by reconciling insights from various disciplines. Here we analyze the human polyomavirus JC (JCV) in Highlanders of Papua New Guinea (PNG), in Austronesian-speaking Tolai people on the island of New Britain, and in nearby non-Austronesian-speaking Baining people. We also characterize JCV from the Chamorro of Guam, a Micronesian population. All JCV strains from PNG and Guam fall within the broad Asian group previously defined in the VP1 gene as Type 2 or Type 7, but the PNG strains were distinct from both genotypes. Among the Chamorro JCV samples, 8 strains (Guam-1) were like the Type 7 strains found in Southeast Asia, while nine strains (Guam-2) were distinct from both the mainland strains and most PNG strains. We identified three JCV variants within Papua New Guinea (PNG-1, PNG-2 and PNG-3), but none of the Southeast Asian (Type 7) strains. PNG-1 strains were present in all three populations (Highlanders and the Baining and Tolai of New Britain), but PNG-2 strains were restricted to the Highlanders. Their relative lack of DNA sequence variation suggests that they arose comparatively recently. The single PNG-3 strain, identified in an Austronesian-speaking Tolai individual, was closely related to the Chamorro variants (Guam-2), consistent with a common Austronesian ancestor. In PNG-2 variants a complex regulatory region mutation inserts a duplication into a nearby deletion, a change reminiscent of those seen in the brains of progressive multifocal leukoencephalopathy patients. This is the first instance of a complex JCV rearrangement circulating in a human population.

Evolution of human polyomavirus JC

More than 20 near full-length genome sequences have been reported for human polyomavirus JC (JCV). These have previously been classified into seven genotypes, and additional subtypes, which exhibit geographical associations. One of these genotypes, Type 4, has been suggested to be a recombinant of Types 1 and 3. We have investigated the pattern of diversity, and evolutionary relationships, among these sequences. In direct contradiction of a recent report, we found that different phylogenetic methods gave consistent results for the phylogenetic relationships among strains. The single known strain representing Type 5 was shown to be a mosaic of sequences from Types 2 and 6, although whether this recombination occurred in vivo or in vitro is not clear. In contrast, there was no substantial evidence that Type 4 strains are recombinant; rather they seem to be simply divergent examples of Type 1. On the assumption that the major genotypes of JCV diverged with human populations, the rate of synonymous nucleotide substitution was estimated to be around 4x10(-7) per site per year, about 10 times higher than a previous estimate for primate polyomaviruses.