The sequence of the A gamma globin gene in a G gamma beta+ type of hereditary persistence of fetal haemoglobin.

The sequence of the A gamma globin gene from the affected chromosome of an individual heterozygous for the G gamma beta+ type of hereditary persistence of fetal haemoglobin (G gamma beta+ HPFH) is reported. With two exceptions, it is identical to one of the two allelic A gamma globin genes already sequenced and there is therefore no change which could explain the absence of its expression in the face of the persistent G gamma globin expression which is a feature of this condition.

Genetic organization of the polymorphic equine alpha globin locus and sequence of the BII alpha 1 gene.

The equine alpha globin gene complex comprises two functional alpha genes and an alpha-like pseudogene arranged in the order 5'-alpha 2-(5kb)-alpha 1-(3kb)-psi alpha-3'. A single (embryonic) zeta-like sequence lies within a 12 kb region 5' to the alpha 2 gene. We have determined the sequence of the alpha 1 gene of the BII haplotype, one of two most common haplotypes (the other being BI) which encode alpha globins with either Tyr (BI) or Phe (BII) at codon 24 in both linked alpha genes. In BI and BII the non-allelic alpha 2 and alpha 1 genes respectively code for Gln or Lys at codon 60, thus accounting for the 4 alpha globin types seen in BI/BII heterozygotes. Genomic restriction enzyme maps of the BII alpha complex (24Phe/60Lys,Gln) and the allelic BI (24Tyr/60Lys,Gln) are identical to each other, and to those of a rarer normal haplotype, A, which encodes only alpha 24Tyr/60Gln globin, and a low expression mutant of BII which encodes only 24Phe/60Lys globin. These two latter haplotypes must therefore have a linked pair of alpha genes, as in BI and BII, but with identical coding properties, and it is suggested that this has arisen by gene conversion.

The molecular basis of alpha-thalassaemia in Thailand.

The molecular basis of alpha-thalassaemia has been established in 48 Thai subjects with Hb H disease and 15 with the Hb Bart's hydrops fetalis syndrome. This study has shown that in this population there are at least 18 different types of chromosome carrying seven independent alpha-thalassaemia mutations one of which is a novel deletion removing the entire alpha-globin gene complex. Although there are a limited number of alpha-thalassaemia determinants in the Thai population, there is a remarkable degree of variation in the genetic markers which flank them. These markers may be of value in establishing the evolutionary history of the alpha-thalassaemias.

Allelic variation and linkage properties of a highly polymorphic restriction fragment in humans.

The region between the human zeta-globin gene and the pseudo-zeta gene contains a stretch of tandemly reiterated 36 base-pair sequence elements. The structure of this locus offers the potential for unequal crossover events or slippage during replication to generate allelic variation in the length of restriction fragments spanning this region. The extent of allelic variation at this locus has been investigated in different populations at a high level of resolution. As many as ten discrete fragment lengths were observed whereas only three had been detected previously at a lower level of resolution. The linkage of alleles at this locus to closely flanking markers indicates that they are inherited as stable Mendelian traits over many generations, and therefore this and similar regions may provide highly polymorphic markers which will be of great value in genetic analysis of the human genome.

Alpha-thalassaemia caused by a polyadenylation signal mutation.

Most eukaryotic messenger RNAs have the sequence AAUAAA 11-30 nucleotides from the 3'-terminal poly(A) tract. Since this is the only significant sequence homology in the 3' non-coding region it has been suggested that it may be a recognition site for enzymes involved in polyadenylation and/or termination of polymerase II transcription. This idea is strengthened by observations on the effect of deletion mutations in or around the AATAAA sequence on polyadenylation of late simian virus 40 (SV40) mRNA; removal of this sequence prevents poly(A) addition. Naturally occurring variants of this hexanucleotide are rare and hitherto their functional significance has not been assessed. We have now identified a human alpha 2-globin gene which contains a single point mutation in this hexanucleotide (AATAAA leads to AATAAG). The paired alpha 1 gene on the same chromosome is completely inactivated by a frame-shift mutation. This unique combination has enabled the expression of the mutant alpha 2 gene to be studied in vivo where it has been found that the accumulated level of alpha 2-specific mRNA in erythroid cells is reduced. Furthermore, readthrough transcripts extending beyond the normal poly(A) addition site are detected in mRNA obtained from HeLa cells transfected with cloned DNA from the mutant alpha 2 gene, suggesting that the single nucleotide change in the AATAAA sequence is the cause of its abnormal expression.

Molecular basis of length polymorphism in the human zeta-globin gene complex.

The length polymorphism between the human zeta-globin gene and its pseudogene is caused by an allele-specific variation in the copy number of a tandemly repeating 36-base-pair sequence. This sequence is related to a tandemly repeated 14-base-pair sequence in the 5' flanking region of the human insulin gene, which is known to cause length polymorphism, and to a repetitive sequence in intervening sequence (IVS) 1 of the pseudo-zeta-globin gene. Evidence is presented that the latter is also of variable length, probably because of differences in the copy number of the tandem repeat. The homology between the three length polymorphisms may be an indication of the presence of a more widespread group of related sequences in the human genome, which might be useful for generalized linkage studies.

Multiple arrangements of the human embryonic zeta globin genes.

Rearrangements which are most readily explained by homologous crossover between misaligned segments of DNA in the region of the human embryonic zeta (zeta) globin genes have been identified in individuals of three different racial origins. These recombination events have resulted in a surprisingly high prevalence of chromosomes with single (0.4%) and triplicated (1.3%) zeta genes with apparently no significant effect on the phenotype.

Highly variable regions of DNA flank the human alpha globin genes.

A series of restriction fragment length polymorphisms which are due to DNA rearrangements have been identified within two highly variable regions flanking the human alpha globin genes. The existence of such highly polymorphic areas provides a large number of individual genetic markers for the alpha globin gene cluster on chromosome 16. If, as seems likely, such regions occur frequently throughout the human genome they should be of considerable value in the antenatal diagnosis of genetic disease.