Increased Y-chromosome resolution of haplogroup O suggests genetic ties between the Ami aborigines of Taiwan and the Polynesian Islands of Samoa and Tonga

The Austronesian expansion has left its fingerprint throughout two thirds of the circumference of the globe reaching the island of Madagascar in East Africa to the west and Easter Island, off the coast of Chile, to the east. To date, several theories exist to explain the current genetic distribution of Austronesian populations, with the “slow boat” model being the most widely accepted, though other conjectures (i.e., the “express train” and “entangled bank” hypotheses) have also been widely discussed. In the current study, 158 Y chromosomes from the Polynesian archipelagos of Samoa and Tonga were typed using high resolution binary markers and compared to populations across Mainland East Asia, Taiwan, Island Southeast Asia, Melanesia and Polynesia in order to establish their patrilineal genetic relationships. Y-STR haplotypes on the C2 (M38), C2a (M208), O1a (M119), O3 (M122) and O3a2 (P201) backgrounds were utilized in an attempt to identify the differing sources of the current Y-chromosomal haplogroups present throughout Polynesia (of Melanesian and/or Asian descent). We find that, while haplogroups C2a, S and K3-P79 suggest a Melanesian component in 23%-42% of the Samoan and Tongan Y chromosomes, the majority of the paternal Polynesian gene pool exhibits ties to East Asia. In particular, the prominence of sub-haplogroup O3a2c* (P164), which has previously been observed at only minimal levels in Mainland East Asians (2.0-4.5%), in both Polynesians (ranging from 19% in Manua to 54% in Tonga) and Ami aborigines from Taiwan (37%) provides, for the first time, evidence for a genetic connection between the Polynesian populations and the Ami.     

Redesign of a protein–peptide interaction: Characterization and applications

The design of protein–peptide interactions has a wide array of practical applications and also reveals insight into the basis for molecular recognition. Here, we present the redesign of a tetratricopeptide repeat (TPR) protein scaffold, along with its corresponding peptide ligand. We show that the binding properties of these protein–peptide pairs can be understood, quantitatively, using straightforward chemical considerations. The recognition pairs we have developed are also practically useful for the specific identification of tagged proteins. We demonstrate the facile replacement of these proteins, which we have termed T‐Mods (TPR‐based recognition module), for antibodies in both detection and purification applications. The new protein–peptide pair has a dissociation constant that is weaker than typical antibody–antigen interactions, yet the recognition pair is highly specific and we have shown that this affinity is sufficient for both Western blotting and affinity purification. Moreover, we demonstrate that this more moderate affinity is actually advantageous for purification applications, because extremely harsh conditions are not required to dissociate the T‐Mod‐peptide interaction. The results we present are important, not only because they represent a successful application of protein design but also because they help define the properties that should be sought in other scaffolds that are being developed as antibody replacements.     

陕西汉族人群12号染色体上7个STR基因座的遗传多态性分析

分析了中国汉族人群中12号染色体上7个短串联重复序列（short tandem repeat,STR）基因座的多态性。 采用荧光标记基因扫描对12号染色体上D12S1718、D12S1675、D12S358、D12S367、D12S1638、D12S1646和D12S1682基因座在80名陕西咸阳、榆林汉族人中的遗传多态性进行分析。结果在中国汉族人群中, D12S1718、D12S1675、D12S358、D12S367、D12S1638、D12S1646和D12S1682基因座分别检出7、10、8、8、6、9和11个等位基因,10、17、18、18、14、18和26个基因型,杂合度分别为44.28％、66.10％、78.89％、77.89％、73.69％、74.55％和82.39％。表明这7个STR基因座在中国人群中有较好的多态性,其基因型分布均符合Hard－Weinberg平衡（P>0.05）。     

The contribution of tandem repeat number to the O-glycosylation of mucins

The serine- and threonine-rich tandem repeat (TR) units that make up the characteristic feature of mucin glycoproteins are often polymorphic with substantial genetic variation in TR number. The precise effect of TR number on O-glycosylation is not fully understood, although the TR number of several mucins may be associated with apparent susceptibility to certain human diseases. To evaluate the contribution of TR number to O-glycosylation, we generated a series of chimeric mucins carrying increasing numbers of TR units from the MUC5B mucin in the context of an epitope-tagged MUC1 mucin backbone. These mucins were expressed in Caco2 colon carcinoma cell clones and purified by immunoprecipitation. O-Glycosylation was investigated by western blotting with antibodies to known carbohydrate structures and by fast atom bombardment-mass spectrometry. Additional carbohydrate epitopes were detected with antibodies on chimeric mucins with a higher TR number in comparison to those with fewer TRs. Using mass spectrometry, higher-molecular-weight glycans were detected more frequently on the mucins with extended TRs compared to those with fewer TRs. However no novel carbohydrate structures were seen, suggesting that TR number does not affect the specificity of O-glycosylation.     

Use of short microsatellites from database sequences to generate polymorphisms among Lycopersicon esculentum cultivars and accessions of other Lycopersicon species

A search of nearly 2000 sequences from Solanaceae species in the EMBL and Genbank databases yielded 220 microsatellites. Among these were 80 microsatellites from 675 Lycopersicon entries. Dinucleotide repeats, as well as (CAA)_n and (TAA)_n repeats, were over-represented in non-coding DNA. The other trinucleotide repeats were predominantly found in exonic DNA. PCR analysis of 44 of the microsatellite-containing Lycopersicon loci identified 36 primer pairs that yielded well-scorable fragments, or groups of fragments, in L. esculentum cultivars and accessions of Lycopersicon species. Twenty-nine of these amplified bands that were polymorphic among the four Lycopersicon species. Ten primer pairs generated polymorphic bands among seven tomato cultivars. Upon examining the number of microsatellites and the degree of polymorphisms in relation to the repeat type and motif, the type of DNA the microsatellite resided in, the length of the microsatellite, and the presence of imperfections in the microsatellite, only two significant correlations were found. (i) Imperfect repeats were less polymorphic among species than perfect repeats. (ii) The percentage of loci polymorphic among cultivars increased from 6% for the shortest loci (with eight or less repeat units) to 60% for the group with the longest repeats (12 repeat units or longer). Among the species, however, all length classes contained about 83% polymorphic loci. In general, 2–4 alleles were found for each locus among the samples of the test set. In a few cases, up to eight alleles were found. A combination of these microsatellite loci can therefore be useful in distinguishing cultivars of tomato, which are genetically very closely related to each other. Received: 9 August 1996 / Accepted: 23 August 1996     

A genetic comparison of two alleged subspecies of Philippine cynomolgus macaques

Two subspecies of cynomolgus macaques (Macaca fascicularis) are alleged to co‐exist in the Philippines, M. f. philippensis in the north and M. f. fascicularis in the south. However, genetic differences between the cynomolgus macaques in the two regions have never been studied to document the propriety of their subspecies status. We genotyped samples of cynomolgus macaques from Batangas in southwestern Luzon and Zamboanga in southwestern Mindanao for 15 short tandem repeat (STR) loci and sequenced an 835 bp fragment of the mtDNA of these animals. The STR genotypes were compared with those of cynomolgus macaques from southern Sumatra, Singapore, Mauritius and Cambodia, and the mtDNA sequences of both Philippine populations were compared with those of cynomolgus macaques from southern Sumatra, Indonesia and Sarawak, Malaysia. We conducted STRUCTURE and PCA analyses based on the STRs and constructed a median joining network based on the mtDNA sequences. The Philippine population from Batangas exhibited much less genetic diversity and greater genetic divergence from all other populations, including the Philippine population from Zamboanga. Sequences from both Batangas and Zamboanga were most closely related to two different mtDNA haplotypes from Sarawak from which they are apparently derived. Those from Zamboanga were more recently derived than those from Batangas, consistent with their later arrival in the Philippines. However, clustering analyses do not support a sufficient genetic distinction of cynomolgus macaques from Batangas from other regional populations assigned to subspecies M. f. fascicularis to warrant the subspecies distinction M. f. philippensis. Am J Phys Anthropol 155:136–148, 2014. © 2014 Wiley Periodicals, Inc.     

Development of a novel,high resolution melting analysis based genotyping method for Cryptosporidium parvum

This study employed the post-real-time PCR application, high resolution melting (HRM) analysis, in order to differentiate between characterised clinical and reference Cryptosporidium parvum samples obtained from Cork University Hospital (Cork, Ireland) and the Cryptosporidium Reference Unit (Swansea, Wales). A sample set composed of 18 distinct C. parvum gp60-subtypes of the IIa gp60-subtype family (an allele family accounting for over 80% of all cryptosporidiosis cases in Ireland) was employed. HRM analysis-based interrogation of the gp60, MM5 and MS9-Mallon tandem repeat loci was found to completely differentiate between 10 of the 18 studied gp60-subtypes. The remaining eight gp60-subtypes were differentiated into three distinct groupings, with the designations within these groupings resolved to two to three potential gp60-subtypes.The current study aimed to develop a novel, reproducible, real-time PCR based multi-locus genotyping method to distinguish between C. parvum gp60-subtypes. These preliminary results support the further expansion of the multi-locus panel in order to increase the discriminatory capabilities of this novel method.