Gm and Inv allotypes in a Gypsy sample.

Serum samples from 226 Gypsies were tested for Gm(1,2,4,5,8,10,11,14,17,21,23,25) and for Inv(1,2). The Gm phenotypes found are very numerous and the more frequent among this population are: Gm(4,5, 8,10,11,14,17,23,25) and Gm(1,2,4,5,8,10,11,14,17,21,23,25). All the phenotypes except three can be explained by nine haplotypes: Gm4,5,8,10,11,14,23,25, Gm1,4,5,8,10,11,14,23,25, Gm4,5,8,10,11,14,25, Gm1,17,21, Gm1,10,11,17,25, Gm1,2,17,21, Gm1,8,17,21, Gm1,8,17,21,23 and Gm1,5,10,11,14,17. The haplotypes Gm1,17,21, Gm1,2,17,21, Gm4,5,8,10,11,14,25 (with or without Gm[ 3]) are all three common among Caucasoids, Gm1,4,5,10,11,14,23,25 (common among Mongoloids) and Gm1,5,10,11,14,17 (common to Negroids). For the Inv system, this population possesses a very low frequency of Inv(1) and Inv(2).     

Gm and Inv allotypes in French Guiana Indians.

Data from 302 individuals belonging to three populations of French Guiana Indians are reported. All the phenotypes except two can be explained by three haplotypes: Gm1,21, Gm1,2,21 and Gm1,10,11,25. The gene frequencies found in the present study are generally in accordance with those previously described among other South American Indians. For the Inv1,2 gene a high value has been found for the Wayanas and the Oyampis, but a difference appears for the Emerillons who possess a low frequency.     

Gm and Inv allotypes of some Sidamo Ethiopians

One hundred and forty serum samples from Ethiopians from three tribes of the Sidamo group were tested for their Gm and Inv phenotypes. The Gm antigens 1,2,3,5,6,13,14,21 were determined on all samples, and Gm(15) and Gm(16) were determined on selected samples. All samples were tested for Inv(1), and those positive for Inv(1) were tested for Inv(3). The samples fall into 18 Gm phenotypes and require seven haplotypes to explain them. The data indicate that these Ethiopians have Negroid, Caucasoid, and Bushmanoid ancestry, with the latter constituting a relatively small proportion of the ancestry and the former two contributing about equally to the remainder. The data are consistent with the conclusions of cultural anthropologists.     

The Gm and Inv allotypes of some Ashkenazic Jews living in Northern U.S.A

Determination of the Gm haplotypes among the serum samples of 249 Ashkenazic Jews living in northern U.S.A. has confirmed the presence of Black African admixture and has established the presence of San (Bushman) admixture. A rough estimate indicates that the haplotypes from these sources contribute about 2% of the genome of the people sampled. The Inv allele frequency is very low (0.037 ± 0.009). This has been found in other Jewish populations and may be characteristic of Jews.     

Immunoglobulin allotypes of European populations. II.Gm, Am and Km(Inv) allotypic markers in Czechoslovakians.

The distribution of G1m(f,z,a, and x), G2m(n), G3m(b0, b1, b3, b5, c3, c5, g, s, t, and v), A2m(1 and 2) and Km(1) (formerly Inv[1]) allotypic determinants has been examined in a series of Czechoslovakian blood donors. The results indicate that Gmza;-;gvA2m1, Gmzax;-;gvA2m1, Gmf;n;bvA2m1 and Gmf;-;bvA2m1 are present in polymorphic frequencies. Further, 9 idiomorphic phenotypes were observed; however, without family data it was not possible to exactly define the majority of these. The observed frequencies of Gmza;g, Gmzax;g and Gmf;b and Km1 are similar to those observed previously in Czechoslovakians and similar to those observed in adjacent populations, though different from those observed in Western Europeans, primarily due to a higher frequency of Gmf;b in Czechoslovakians.     

Gm(1) and Gm(2) immunoglobulin allotypes in patients with malignant melanoma.

Gm allotype markers were determined in sera from 71 melanoma patients and 400 control persons. There was no significant difference between both groups in Gm distribution. The results were compared to a recent report. Furthermore, in 25 malanoma patients the capacity of serum to interfere with cell-mediated cytotoxicity (CMC) of autologous lymphocytes was determined and related to the Gm allotype.     

Gm and Inv (Km) studies of melanesian people on the Huon Peninsula in northeast Papua New Guinea: Polymorphism for a Gm1,5,10,11,13,14,17,21,26 haplotype

Blood samples from 448 people living in six villages in the Huon Peninsula in northeast Papua, New Guinea, were tested for Gm(1,2,3,5,6,10,11,13,14,17,21,24,26) and Inv(1) [Km(1)]. All the people are non-Austronesian (NAN) speakers. As expected, there was a low frequency of the Gm^{1,3,5,10,11,13,14,26} haplotype, but in contradiction to expectations there was a complete absence of the Gm^1,2,17,21,26 haplotype. In addition, samples from people in one village (Yupna) and probably those for two other villages (Irumu 13 and 14) have the rare haplotype Gm^{1,5,10,11,13,14,21,26} at polymorphic frequencies. Two samples from people living in Yupna had the rare phenotype Gm(1,3,17,21,26), indicating the presence of any one of several rare haplotypes that had been observed in other populations. These are discussed.     

Gm and Km allotypes in 74 Chinese populations: a hypothesis of the origin of the Chinese nation

Summary This paper reports the distribution of immunoglobulin Gm and Km allotypes in 74 Chinese geographical populations. These populations are derived from 24 nationalities comprising 96.6% of the total population of China. A total of 9,560 individuals were phenotyped for Gm(1,2,3,5,21) factors, and 9,611 were phenotyped for Km(1). Phylogenetic trees were constructed on the basis of Gm haplotype frequencies and genetic distances. The results of cluster analysis show the heterogeneity of the Chinese nation, and confirm the hypothesis that the modern Chinese nation originated from two distinct populations, one population originating in the Yellow River valley and the other originating in the Yangtze River valley during early neolithic times (3,000–7,000 years ago). Frequencies of the Gm haplotype of 74 Chinese populations were compared with those of 33 populations from major racial groups. The results suggest that during human evolution, the Negroid group and Caucasoid-Mongoloid group diverged first, followed by a divergence between the Caucasoid and Mongoloid. Interrace divergence is high in comparison with intrarace divergence. There appear to be two distinct subgroups of Mongoloid, northern and southern Mongoloid. The northern and southern Mongoloid have Gm^1;21 and Gm^1,3;5 haplotypes as race-associate markers, respectively. Furthermore, the Caucasian-associated haplotype Gm^3;5 was found in several of the minorities living in the northwest part of China. The presence of the Gm^3;5 haplotype is attributed to the Caucasians living in Central Asia throughout the Silk Road. The amount of Caucasian admixture has been estimated. In contrast to the Gm haplotype distribution, Km¹ gene frequencies showed a random distribution in the populations studied.     

Gammaglobulin groups (Gm and Inv) of various Southern African populations

Data are presented on the distribution of the Gm and Inv groups in approximately 3500 individuals belonging to a number of diverse Southern African populations. The indigenous peoples show the presence of the Gm alleles known to occur in Negroes (Gm^{1, 5, 13, 14}, Gm^{1, 5, 6, 14} and Gm^{1, 5, 6}) but the Bushmen possess some of them in very low frequencies and have, in addition and in appreciable frequencies the Gm¹ and Gm^{1, 13} alleles which have not been reported as occurring in West African populations. The distribution of the Gm^{1, 13} allele in various Bantu-speaking tribes of the sub-continent reveals a marked cline, increasing from north to south along the eastern seaboard. The correlation between the frequency of Gm^{1, 13} and the Khoisan morphological, features present in a number of the tribes, and with the linguistic evidence which has been used to group them is high. The Bushmen possess a Gm^{1, 5} allele and may also have a Gm^{1, 5, 13, 14, 17, 21} allele. A Gm^{1, 2, 5, 13, 14, 17} allele seems to be present in the Bantu. Its presence in Eastern New Guinea would also appear to be indicated by the population data presented here.     

Distribution of Gm and Km allotypes among five populations in China

Serum samples from five populations in China [173 from Huhehote (Naimengu Zhizhiqu), 195 from the Beijing area, 131 from Hefei (Anhui Province), 155 from Hangzhou (Zhejiang Province), and 152 from Guangzhou (Guangdong Province)] were tested for G1m(1, 2, 3, and 17), G2m(23), G3m(5, 10, 11, 13, 14, 15, 16, 21, and 26), and Km(1). The Gm pattern of the Chinese populations are characterized by the presence of four haplotypes, Gm1, 17;..;21, 26, Gm1, 2, 17;..;21, 26, Gm1, 17;..;10, 11, 13, 15, 16, and Gm1, 3;23;5, 10, 11, 13, 14, 26, which are characteristic of Mongoloid populations. Agreement was obtained in all Chinese samples between the observed and expected frequencies on the basis of the Hardy-Weinberg equilibrium of phenotypes. Heterogeneity tests of the haplotypic distributions among the five populations showed no significant differences in the distributions of Gm phenotypes between Huhehote and Beijing nor between Hefei and Hangzhou, whereas highly significant differences were observed among the three districts: northern part (Huhehote and Beijing), central part (Hefei and Hangzhou), and southern part (Guangzhou). The data indicate a south to north genocline, ranging from Huhehote to Guangzhou in which Gm1, 17;..;21, 26 changes from 0.471 to 0.183, Gm1, 17;..;10, 11, 13, 15, 16 from 0.097 to 0.033, and Gm1, 3;23;5, 10, 11, 13, 14, 26 from 0.229 to 0.730. In contrast to the Gm system, no significant regional differences in the frequencies of the Km1 allele were observed among the five populations.     

The effect of the interaction of heavy and light chains of IgG on the Gm and Inv antigens

Studies of isolated polypeptide chains, of reconstituted, and of intact IgG show that the antigens present on the Fab fragment, Gm (3), Gm (4), and Inv (1), depend upon the interaction of heavy and light chains for their full antigenic expression, while the antigens of the Fc portion of the heavy chain, Gm (1), Gm (5), Gm (13), and Gm (14), have the same antigenicity in intact IgG, in isolated heavy chains, and in reconstituted IgG. Hybridization experiments using Bence-Jones protein light chains indicate that different homogeneous populations of light chains differ in their ability to restore Gm (3) and Gm (4) antigenicity and that this ability is independent of light-chain antigenic type.The investigations reported in this paper were supported in part by National Institutes of Health Grant GM 07214.Recipient of support from National Institutes of Health Training Grant 2T1 GM 226.