The gene profile of Arabic-speaking Moroccans has been compared with those of other Mediterranean populations in order to provide additional information about the history of their origins. Our HLA data suggest that most Moroccans are of a Berber (Imazighen) origin and that Arabs who invaded North Africa and Spain in the 7th century A.D. did not substantially contributed to the gene pool; however, they imposed their advanced culture and their religion. Present-day Egyptians are also related to Moroccan Berbers and this supports an ancient Saharan origin for part of the present-day Mediterraneans, particularly for the Arabic-speaking ones (also Algerians) and also for the older substratum of Mediterranean people.
The Cretan HLA gene profile has been compared with those of other Mediterranean populations in order to provide additional information regarding the history of their origins. The allele frequencies, genetic distances between populations, relatedness dendrograms and correspondence analyses were calculated. Our results indicate that the Indoeuropean Greeks may be considered as a Mediterranean population of a more recent origin (after 2000 B.C.), while all other studied Mediterraneans (including Cretans) belong to an older substratum which was present in the area since pre-Neolithic times. A significant Turkish gene flow has not been detected in the Greek or Cretan populations, although Greeks and Turks have two high frequency HLA-DRB-DQB haplotypes in common. It is proposed that Imazighen (Caucasoid Berbers living at present in the North African coast and Saharan areas) are the remains of pre-Neolithic Saharan populations which could emigrate northwards between about 8000-6000 B.C., when desert desiccation began. They also could be part of the stock that gave rise to Sumerians, Cretans and Iberians; this is supported by both linguistic and HLA genetic data.
The HLA allele frequency distribution of the Mexican Mazatecan Indians (Olmec culture) has been studied and compared with those of other First American Natives and worldwide populations (a total of 12,100 chromosomes; 6,050 individuals from 59 different populations). The main conclusions are: 1) An indirect evidence of Olmec and Mayan relatedness is suggested, further supporting the notion that Olmecs may have been the precursors of Mayans; 2) Language and genetics do not completely correlate in microenvironmental studies; and 3) Peopling of the Americas was probably more complex than postulated by Greenberg and others (three peopling waves). Significant genetic input from outside is not noticed in Meso and South American Amerindians according to the phylogenetic analyses; while all world populations (including Africans, Europeans, Asians, Australians, Polynesians, North American Na-Dene Indians and Eskimos) are genetically related. Meso and South American Amerindians tend to remain isolated in the Neighbor-Joining, correspondence and plane genetic distance analyses.
The HLA-B locus is the most polymorphic of the class I genes encoded within the human major histocompatibility complex. This polymorphism is mainly located in exons 2 and 3, which code for the molecule's alpha1 and alpha2 domains and includes the antigenic peptide binding site. However, information about adjacent non-coding regions (introns 1 and 2) has not been extensively reported but could be very important in establishing an understanding of the evolutionary mechanisms involved in the polymorphism generation of HLA-B and the Mhc loci. In the present work, introns 1 and 2 of 14 HLA-B alleles are studied and their significance is discussed; 10 have been sequenced in our own laboratory and the other 4 have been previously reported by others. Different serological families share the complete intron 1 sequence; at this region, 12 out of 14 HLA-B alleles could be included in four groups with the same intron 1 sequence: a) B*0702, B*4201, B*4801; b) B*27052, B*4002, B*4011; c) B*40012, B*4101, including B*4501, B*5001 (these latter two alleles have specific characteristics in both introns 1 and 2, which may reflect a common evolutionary pathway); and d) B*44031, B*44032. The other alleles, B*1402, and B*1801, do not have identical intron 1 sequences compared to any of the described groups, but share many similarities with them. The B*1801 evolutionary pathway seems to be very specific since it branches separately from other alleles both in intron 1 and intron 2 dendrograms. On the other hand, HLA-B allelic group distribution and similarities according to intron 1 sequences were not confirmed when using intron 2, especially in the cases of B*4002, B*4101 and B*4801. This would suggest that both point mutations fixed by genetic drift and gene conversion events are involved in HLA-B diversification. The latter events could be supported by the strong homology between intron 1 and, to a lesser extent, intron 2, and also the CG content within them. Finally, the precise knowledge of these non-coding regions could be important for developing DNA base typing strategies for the HLA-B alleles.
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