An Apparent Connection between Histidine, Recombination, and Repair in Neurospora

Two mutants of Neurospora crassa, uvs-3 and mei-3, share four properties--UV sensitivity, inhibition by histidine, meiotic blockage when homozygous, and increased duplication instability (due to mitotic crossing over, to deletions or to both). The present paper shows that a third nonallelic mutant, uvs-6, exhibits the same four properties.--Also, the instability of duplications in the absence of any UV-sensitive mutant is increased by the presence of histidine in the growth medium.     

Unequal Crossing Over as the Pathway of Adaptive Homologous Recombination between the Direct DNA Repeats in Tandem Duplications of Escherichia coli

Homologous recombination between direct DNA repeats within the extended tandem duplications in E. coli results from unequal sister-chromosome exchanges. This conclusion follows from the observations on the segregation of completely or partly homozygous diploid segregants by heterozygous duplications. The formation of diploid segregants with preserved heterozygosity for the unselected markers could also result from symmetrical intrachromosomal recombination. Analysis of the segregant genotypes, however, confirmed their formation via unequal crossing over. The data obtained indicated that in tandem duplications segregation of diploid recombinants of different types was preceded by the formation of triplications as the products of unequal sister-chromosome exchanges. In heterozygous duplications, unequal crossing over is manifested as a highly frequent adaptive exchange, providing the survival of the most part of the duplication-carrying cells on selective medium. It is suggested that adaptive mutagenesis can be the consequence of unequal sister crossing over.     

The Instability of Neurospora Duplication Dp(IL-->IR)H4250 , and Its Genetic Control

Previous work (Newmeyer and Taylor 1967) showed that a nontandem duplication, Dp(IL-->IR)H4250, is regularly produced by recombination in crosses heterozygous for the effectively terminal pericentric inversion In(IL-->IR)H4250. The duplications initially have strongly inhibited growth because they are heterozygous for mating type, which behaves like a vegetative-incompatibility (het) locus. Such cultures "escape" from the inhibition as a result of events that eliminate the mating-type heterozygosity. The product of a given escape event may be barren or fertile. (Neurospora duplications are characteristically barren; that is, when crossed, they make many perithecia but few ascospores.)-The present paper reports on a genetic analysis of the instability of Dp(IL-->IR)H4250 . Most of the barren escape products behave as if due either to mitotic crossovers, which make mating type and distal markers homozygous, or to very long deletions which uncover mating type and all distal markers; presumably the latter would retain enough duplicated material to render them barren. It is difficult to distinguish between these two possibilities, but homozygosis seems more probable and has been clearly demonstrated in one case. Only a few barren escapes could be due to short deletions or to changes at the mating-type locus.-The fertile escape products appear to be euploid. Most of these behave as if they arose by precise deletion of one or the other duplicated segment, thus restoring one of the parental sequences. A large majority of the precise deletions restore normal sequence; only a few restore inversion sequence. Preferential restoration of the normal sequence has also been found by other workers for Neurospora duplications from several other rearrangements. A hypothesis is presented to explain these findings; it is posulated that the precise deletions result from mitotic crossing over in homologous material located at chromosome tips and tip-break-points.-There is a smaller group of fertile escapes that are unlike either parental sequence; at least one of these involves a chromosome break outside the duplicated region.-Duplications in which the vegetative incompatibility is suppressed by the unlinked modifier tol are extremely barren; they only rarely lose a duplicated segment so as to become fertile.-The instability of Dp(IL-->IR)H4250 , with and without tol, is markedly altered by factors in the genetic background. The two factors studied in detail have qualitatively different effects.     

Procedures for identifying S-allele genotypes of Brassica

Summary Procedures are described for efficient selection of: (1) homozygous and heterozygous S-allele genotypes; (2) homozygous inbreds with the strong self- and sib-incompatibility required for effective seed production of single-cross F₁ hybrids; (3) heterozygous genotypes with the high self- and sib-incompatibility required for effective seed production of 3- and 4-way hybrids.From reciprocal crosses between two first generation inbred (I₁) plants there are three potential results: both crosses are incompatible; one is incompatible and the other compatible; and both are compatible. Incompatibility of both crosses is useful information only when combined with data from other reciprocal crosses. Each compatible cross, depending on whether its reciprocal is incompatible or compatible, dictates alternative reasoning and additional reciprocal crosses for efficiently and simultaneously identifying: (A) the S-allele genotype of all individual I₁ plants, and (B) the expressions of dominance or codominance in pollen and stigma (sexual organs) of an S-allele heterozygous genotype. Reciprocal crosses provide the only efficient means of identifying S-allele genotypes and also the sexual-organ x S-allele-interaction types.Fluorescent microscope assay of pollen tube penetration into the style facilitates quantitation within 24–48 hours of incompatibility and compatibility of the reciprocal crosses. A procedure for quantitating the reciprocal difference is described that maximizes informational content of the data about interactions between S alleles in pollen and stigma of the S-allele-heterozygous genotype.Use of the non-inbred I_o generation parent as a known heterozygous S-allele genotype in crosses with its first generation selfed (I₁) progeny usually reduces at least 7 fold the effort required for achieving objectives 1, 2, and 3, compared to the method of making reciprocal crosses only among I₁ plants.Identifying the heterozygous and both homozygous S-allele genotypes during the I₁ generation facilitates, during subsequent inbred generations, strong selection for or against modifier genes that influence the intensity of self- and sib-incompatibility. Selection for strong self and sib incompatibility can be effective for both homozygous inbreds and also for the S-allele heterozygote, thus facilitating production of single-cross F₁ hybrids and also of 3-and 4-way hybrids.Department of Plant Breeding and Biometry paper No. 690     

On the toleration of duplications and deletions by the Vicia faba genome

Summary From eight pairs of crosses between differently reconstructed diploid karyotypes of Vicia faba, the progeny after selfing of plants heterozygous for both parental chromosome reconstructions were inspected for occurrence and transmission of duplications and deletions of defined chromosome segments, comprising together about one third of the metaphase genome length. The duplications and deletions studied involved either one or more chromosome segments of the respective karyotype (0.8%–9.1% of the metaphase length). They arose during meiosis in double heterozygotes by crossing over between partially homologous chromosomes or by mis-segregation from multivalents. While most duplications, provided they were not accompanied by deletions and in dependence on the segment involved, were viable and transmissible, even in homozygous state, deletions had lethal effects on gametes of both sexes.     

Detection of the loss of 1 chromosome from pair III in Saccharomyces cerevisiae yeasts

A diploid strain of Saccharomyces cerevisiae, T6 is described which monitors both mitotic crossing over and induction of aneuploidy. The chromosome III carries recessive markers: rgh12 of "rough colony" phenotype closely linked to centromere, the left arm is marked with his4, the right arm is marked both with thr4 and the locus of mating type alpha. Expression of all the markers on chromosome III leads to formation of colonies which are rough, require histidine and threonine, and are of alpha mating type. These colonies arise as a result of the loss of a chromosome during mitosis, which makes the strain allow detection of monosomic cells formation. Chromosome XV carries two phenotypically distinguishable and recessive alleles of the gene ade2: ade2-192 (causes red coloration of colonies) and ade2-G45 (causes pink coloration of colonies). Mitotic crossing over generates two reciprocal products which can be revealed together in colonies as pink and red sectors in double-spotted colonies. Both double-spotted and monosomic colonies have been obtained after treatment with gamma-rays. The frequency of mitotic crossing over after irradiation by 1000-3000 Gray increased up to 2-3.2% (the spontaneous level was 0.006%), the frequency of aneuploidy was 0.12 to 0.57% at plating immediately after irradiation (the spontaneous monosomics were not observed among 1.5 X 10(5) cells scored). Induction of mitotic crossing over and aneuploidy by benomyl was rather slight (up to 0.05 and 0.006%, respectively).     

Escape from repeat-induced point mutation of a gene-sized duplication in Neurospora crassa crosses that are heterozygous for a larger chromosome segment duplication

In Neurospora crassa the ability of an ectopic gene-sized duplication to induce repeat-induced point mutation (RIP) in its target gene was suppressed in crosses that were heterozygous for another larger chromosome segment duplication. Specifically, the frequency of RIP in the erg-3 gene due to a 1.3-kb duplication was reduced if the chromosome segment duplications Dp(IIIR > [I;II]) AR17, Dp(VIR > IIIR) OY329, or Dp(IVR > VII) S1229 were present in either the same or the other parental nucleus of the premeiotic dikaryon. We suggest that the larger duplications act as sinks to titrate the RIP machinery away from the smaller duplication. In contrast, RIP efficiency was relatively unaffected in comparably unproductive interspecies crosses with N. intermedia and N. tetrasperma. These findings offer a novel explanation for the observed persistence of the transposable element Tad in only a subset of Neurospora strains.     

Heterokaryon Incompatibility Genes in NEUROSPORA CRASSA Detected Using Duplication-Producing Chromosome Rearrangements

Evidence is presented for five or six previously undetected heterokaryon incompatibility (het) loci, bringing to about ten the number of such genes known in Neurospora crassa. The genes were detected using chromosome duplications (partial diploids), on the basis of properties previously known for het genes in duplications. Duplications homozygous for het genes are usually normal in growth and morphology, whereas those heterozygous are strikingly different. The heterozygotes are inhibited in their initial growth, produce brown pigment on appropriate medium, and later "escape" from their inhibition, as a result of somatic events, to produce wild-type growth. - Five normal-sequence strains were crossed to 14 duplication-producing chromosome rearrangements, and the duplication progeny were examined for properties characteristic of duplications heterozygous for known het genes. Each cross produced duplications for a specific region of the genome, depending on the rearrangement. Normal-sequence strains were wild types from nature, chosen from diverse geographic locations to serve as sources of genetic variation. - The duplication method was very effective. Most of the longer duplications uncovered het genes. The genes are: het-5 (on linkage group IR, in the region covered by duplications produced using rearrangement T (IR LEADS TO VIR)NM103), het-6 (on IIL, covered by T(IIL LEADS TO VI)P2869 and T(IIL LEADS TO IIIR)AR18 duplications), het-7 (tentatively assigned to IIIR, T(IIIR LEADS TO VIL)D305), het-8 (VIL, T(VIL LEADS TO IR)T39M777), het-9 (VIR LEADS TO IVR)AR209), and het-10 (VIIR, T(VIIR LEADS TO IL)5936.     

Marginal distribution and high heterozygosity of asexual Caloglossa vieillardii (Delesseriaceae,Rhodophyta) along the Australian coasts

In animals and land plants, many asexual species originate through inter‐ or intraspecific crosses, and such heterozygous asexuals frequently are more abundant than their sexual relatives in marginal habitats. Although asexual species have been reported in various macroalgal taxa, detailed information regarding their distribution, heterozygosity, and origin is limited. Because many asexual tetrasporophyte strains of Caloglossa vieillardii have been isolated from South Australia, far from their core tropical habitats, we re‐examined the distribution range of asexual C. vieillardii and genotyped these and other western Pacific strains using an actin gene marker. We confirmed the marginal distribution of the asexuals; however, a small patch of sexual thalli was newly discovered 450 km further west from asexual populations in South Australia. Three heterozygous genotypes and one homozygous genotypes were detected from nine asexual populations; 21 heterozygous strains were obligately asexual, but one homozygous strain suddenly produced sexual gametophytes after several years of culture. We hypothesized that the most abundant heterozygous genotype (defined as type 3/4) in asexual populations occurred by a cross between type 3 and type 4 allele gametophytes, both of which were isolated from the Australian coasts. In the crossing experiments, certain combinations between type 3 females and type 4 males produced tetrasporophytes, which recycled successive tetrasporophytes. In the culture experiments, whereas both sexual and asexual strains successfully produced tetraspores at 12°C, no sexual strains released carpospores below 14°C. However, it is uncertain whether this slight difference of maturation temperature was related to the marginal distribution of asexual C. vieillardii.     

A yeast strain for simultaneous detection of induced mitotic crossing over,mitotic gene conversion and reverse mutation

A diploid yeast strain is described which can be used to study induction of mitotic crossing over, mitotic gene conversion and reverse mutation.Mitotic crossing over can be detected visually as pink and red twin sectored colonies which are due to the formation of homozygous cells of the genotype ade240/ade240 (deep red) and ade-2-119/ade2-119 (pink) from the originally heteroallelic condition ade2-40/ade2-119 which forms white colonies.Mitotic gene conversion is monitored by the appearance of tryptophan non-requiring colonies on selective media. The alleles involved are tryp5-12 and trp5-27 derived from the widely used strain D4.Mutation induction can be followed by the appearance of isoleucine non-requiring colonies on selective media. D7 is homoallelic ilv1-92/ilv1-92. The isoleucine requirement caused by ilv1-92 can be alleviated by true reverse mutation and allele non-specific suppressor mutation.The effects of ethyl methanesulfonate (EMS), nitrous acid, ultraviolet light and hycanthone methanesulfonate were studied with D7 stationary phase cells. Mitotic crossing over as monitored by red/pink twin sectored colonies was almost equally frequent among normal and convertant cells. This showed again that mitotic recombination is not due to the presence fo a few cells committed to meiosis in an otherwise mitotic cell population.The dose-response curves for induction of mitotic gene conversion and reversion of the isoleucine requirement were exponential. In contrast to this, the dose-response curve for induction of twin sectored red and pink colonies reached a plateau at doses giving about 30% cell killing. This could partly be due to lethal segregation in the progeny of treated cells.None of the agents tested would induce only one type of mitotic recombination, gene conversion or crossing over. There was, however, some mutagen specificity in the induction of isoleucine prototrophs.     

UV-Induced mitotic recombination and its dependence on photoreactivation and liquid holding in the rad6-1 mutant of Saccharomyces cerevisiae

Summary Spontaneous and UV-induced mitotic recombination was compared in diploids homozygous for rad6-1 mutation and in the wild-type strain carrying heterozygous markers for detecting gene conversion (hom2-1, hom2-2) and crossing over (adel, ade2). Diploids homozygous for rad6-1 mutation were characterised by an elevated level of spontaneous and UV-induced mitotic recombination, particularly the intergenic events. Exposure of UV-irradiated strains to visible light resulted in an increased survival and decreased level of mitotic recombination. Liquid holding (LH) differentially affected frequency of mitotic intergenic and intragenic recombination in mutant and wild-type strains, being without any significant effect on cell survival. In a mutant strain intragenic recombination is significantly increased, intergenic only slightly. In the wild-type strain intragenic recombination is slightly decreased but intergenic is not changed by LH. Visible light applied after LH had no effect on survival and mitotic recombination in the wild type, while in the mutant strain photoreactivability of survival was fully preserved and accompanied by a decrease in the frequency of intragenic and intergenic recombination. The results suggest that metabolic pathways responsible for restoring cell survival are independent of or only partly overlapping with those concerning recombination events.     

Mutational Analysis of Mating Type Inheritance in Syngen 4 of PARAMECIUM AURELIA

Six genic mutations restricting clones to mating type VII (O) were isolated in syngen 4, Paramecium aurelia. The only three extensively tested were neither allelic nor closely linked. A second type of mutation, allelic to one of the O restricted mutants, was also found. Clones homozygous for this mutant gene were selfers, producing both O and E (VIII) mating types, but only when they were progeny of mating type E parental clones. While all seven mutant genes behaved as recessives in monohybrid crosses, clones heterozygous at two different loci often demonstrated an unanticipated phenotype: selfing. The significance of the findings is discussed in relation to mating type determination and the evolution of mating type systems.     

Epistatic Grouping of Repair-Deficient Mutants in Neurospora: Comparative Analysis of Two uvs-3 Alleles, uvs-6 and Their mus Double Mutant Strains

The nuclease halo mutant, nuh-4, of Neurospora crassa was identified conclusively as an allele of uvs-3, a gene involved in error-prone DNA repair. Like uvs-3, nuh-4 showed spontaneous mutator effects, and any previous contradictory findings were found to be due to newly arisen mutants. In normal strains the two alleles are noncomplementing and indistinguishable for sensitivity to UV and methyl methanesulfonate (MMS). Like uvs-3, nuh-4 lacked secretion of the extracellular enzyme, DNase A, a Ca⁺⁺-dependent strand-nonspecific endonuclease which was found to be phosphate repressible. However, nuh-4 differed from uvs-3 in showing much higher conidial viability and lower sensitivity to ionizing radiation and mitomycin C.——Epistatic relationships of the two uvs-3 alleles with seven other MMS-sensitive mutants were determined and compared with those of the highly X-ray-sensitive mutant, uvs-6. Three epistatic groups were found, based on survival of double mutant strains relative to that of their component single mutant strains after treatment with MMS. Both, uvs-3 and nuh-4, were epistatic to mus-9 which also is a mutator. None of the three produced viable double mutants in crosses to uvs-6. On the other hand, uvs-6, but not the uvs-3 alleles, was found to be epistatic to mus-7 and mus-10. The excision-defective uvs-2 and mus-8 both showed synergism with the uvs-3 alleles and with uvs-6, forming a third, separate epistatic group.     

The effects of tandem duplications on crossing over inDrosophila melanogaster

Each of three tandem duplications,Bar, Beadex ^r49k andDp(I)z-w, when homozygous increases crossing over in their environs in excess of the genetic length of the duplication.Detailed crossing over studies withDp(I)z-w showed that in the duplication homozygotes interference is reduced and when combined with heterologous autosomal inversions, double crossovers occurring in less than 10 map units are readily recovered.These results are interpreted in terms of the concept of effective pairing and suggest that tandem duplications increase crossing over by increasing effective pairing.     

Mating behaviour of Nannizzia otae (=Microsporum canis)

One hundred and ninety-eight isolates of Microsporum canis, obtained from humans and animals in 12 countries, were paired with the two Japanese tester strains of Nannizzia otae (= M. canis), VUT 74037 (CDC B-2094+) and VUT 74039 (CDC B-2095–). One hundred and forty-one (72%) produced either gymnothecia or pseudogymnothecia in crosses with VUT 74037. Fifty-seven (28%) were nonreactive. None of the paired isolates reacted with VUT 74039. The number of nonreactive isolates decreased to 17% when 104 of the 198 isolates were paired with one additional tester strain of each mating type. All sexually reacting strains, however, belonged to the (–) mating type. Crosses between nonreactive isolates did not result in ascocarp formation.The F₁ generations from three different strongly reactive crosses were all characterized by poor ascospore germination. Most of the monoascospore progeny that germinated to form mature colonies were nonreactive in crosses to determine their mating type. Others reacted predominantly as the (+) mating type, thereby precluding the likelihood of an associated lethal factor accounting for the lack of this mating type in our clinical isolates. Several explanations for this phenomenon are presented.     

Cytogenetics of an intrachromosomal transposition in Neurospora

Knowledge of intrachromosomal transpositions has until now been primarily cytological and has been limited to Drosophila and to humans, in both of which segmental shifts can be recognized by altered banding patterns. There has been little genetic information. In this study, we describe the genetic and cytogenetic properties of a transposition in Neurospora crassa. In Tp(IRIL)T54M94, a 20 map unit segment of linkage group I has been excised from its normal position and inserted near the centromere in the opposite arm, in inverted order. In crosses heterozygous for the transposition, about one-fifth of surviving progeny are duplications carrying the transposed segment in both positions. These result from crossing over in the interstitial region. There is no corresponding class of progeny duplicated for the interstitial segment. The duplication strains are barren in test crosses. A complementary deficiency class is represented by unpigmented, inviable ascospores. Extent of the duplication was determined by duplication-coverage tests. Orientation of the transposed segment was determined using Tp x Tp crosses heterozygous for markers inside and outside the transposed segment, and position of the insertion relative to the centromere was established using quasi-ordered half-tetrads from crosses x Spore killer. Quelling was observed in the primary transformants that were used to introduce a critical marker into the transposed segment by repeat-induced point mutation (RIP).     

An insertional translocation in neurospora that generates duplications heterozygous for mating type

In strain T(I-->II)39311 a long interstitial segment is transposed from IL to IIR, where it is inserted in reversed order with respect to the centromere. In crosses of T x T essentially all asci have eight viable, black spores, and all progeny are phenotypically normal. When T(I-->II)39311 is crossed by Normal sequence (N), the expected duplication class is viable while the corresponding deficiency is lethal; 44% of the asci have 8 Black (viable) spores and 0 White (inviable) spores, 41% have 4 Black: 4 White, and 10% have 6 Black: 2 White. These are the ascus types expected from normal centromere disjunction without crossing over (8B:0W and 4B:4W equally probable), and with crossing over between centromere and break point (6B:2W). On germination, 8B:0W asci give rise to only parental types-4 T and 4 N; 4B:4W asci usually give four duplication (Dup) progeny; and 6B:2W asci usually give 2 T, 2 N, 2 Dup. Thus one third of all viable, black ascospores contain duplications.-Recessive markers in the donor chromosome which contributes the translocated segment can be mapped by duplication coverage. Ratios of 2 Dominant: 1 Recessive vs. 1 Dominant: 2 Recessive distinguish location in or outside the transposed segment. Eleven loci including mating type have been shown to lie within the segment, and markers at four loci have been transferred into the segment by meiotic recombination. The frequency of marker transfer indicates that the inserted segment usually pairs with its homologue. Ascus types that would result from single exchanges within the insertion are infrequent, as expected if asci containing dicentric bridges usually do not survive.-Duplication ascospores germinate to produce distinctive inhibited colonies. Later these "escape" to grow like wild type, and genes that were initially heterozygous in the duplication segregate when escape occurs. As with duplications from pericentric inversion In(IL-->IR)H4250 (Newmeyer and Taylor 1967), the initial inhibition is attributed to mating-type heterozygosity, and escape to a somatic event that makes mating type homoor hemizygous.-Twenty additional duplication-generating Neurospora rearrangements are listed and described briefly in an Appendix.     

DEVELOPMENT OF APOGAMIC AMOEBAE FROM HETEROTHALLIC LINES OF A MYXOMYCETE,DIDYMIUM IRIDIS

By making appropriate crosses between heterothallic sexual clones of Didymium iridis we can recover apogamic lines in the F₁ generation. In this organism, heterothallic forms typically produce a haploid myxamoebal stage, but recently two diploid myxamoebal clones homozygous for mating types were discovered. When these are crossed, A²A² x A⁵A⁵, tetraploid Plasmodia are produced which later yield diploid F₁ meiospores. Sixty-four percent of the single-spore-derived clones produce both myxamoebae and Plasmodia, while the remainder do not progress past the myxamoebal stage. These results are consistent with the predictions that from tetraploid nuclei, mating types should segregate in the meiospores in a ratio of 1A²A²:4A²A⁵:1A⁵A⁵, and that myxamoebae heterozygous, A²A⁵, for mating type should yield Plasmodia apogamously. As the means for verifying relative ploidy levels of myxamoebae and Plasmodia, nuclear DNA was measured with a scanning microspectrophotometer.     

Isolation and genetic analysis of nuclease halo (nuh) mutants of Neurospora crassa.

Summary Nuclease halo (nuh) mutants of the ascomycete Neurospora crassa have been isolated which are characterized reduced release of deoxyribonuclease (DNase) activities from colonies grown on sorbose-containing agar media. To identify nuh mutants, mutagenized isolates were transferred to commercial DNase test agar, or grown on minimal medium and then overlayed with agar that contained heat-denatured DNA. DNase activity was visualized by acid precipitation which produced clear rings of digestion (haloes) around the colonies.To identify the number of genes in which mutations lead to reduced release of nuclease activity, eleven nuh mutants were checked for close linkage and linked pairs were tested for complementation. These mutants were assigned to eight genes, and all except one were mapped in six small regions of the Neurospora linkage maps. In addition, among a large number of existing mutants which were tested for nuclease haloes, two mutants were found that showed the Nuh phenotype, namely uvs-3 and uvs-6. One of the isolated nuh mutants was also found to be sensitive to UV and was mapped close to uvs-3; it may represent a new allele of this gene.As a first step towards identification of genuine nuclease mutants, extensively backcrossed strains of mutants from different genes have been assayed for nuclease activity with denatured DNA in extracts. A pronounced reduction, compared to wild type at the same stage of growth, was found in uvs-3 and also in nuh-3, a mutant that is not UV-sensitive.     

Variability of the immunoglobulin heavy chain constant region locus: a population study

The Immunoglobulin Heavy chain Constant region (IGHC) locus is a multigene family composed of highly homologous segments often involved in unequal crossings over that lead to deleted and duplicated haplotypes. The frequencies of these haplotypes in 558 individuals from Lombardy, Veneto, Puglia and Sardinia were determined by Pulsed Field Gel Electrophoresis (PFGE), followed by Southern blotting with four IGHC probes, and compared with those observed in 110 subjects from Piedmont. Twenty deletions and 60 duplications were characterized, all in heterozygous individuals except for 2 homozygous deletions. The differences in frequency between the five populations were not significant. The deletions/duplications involved one or more genes: GP-A2, A1-E and G4 duplications, and A1-E and GP-A2 deletions were the most common. Four new duplications are described: three, involving the genes from GP to A2, from G2 to G4, and G4, are counterparts of known deletions. The fourth duplication spans from GP to G2. A G1 deleted heterozygous individual never previously described in Italy is reported. All the rearranged haplotypes seem to be the result of unequal crossing over. The difference between the number of duplications and deletions was significant in Sardinia, Lombardy, Puglia and in the total of 668 subjects (P < 0.001). This may be due to selection or genetic drift.