Identification of new minimally lost regions on 18q in head and neck squamous cell carcinoma.

Loss of heterozygosity (LOH) on 18q predicts poor survival in head and neck squamous cell carcinomas (HNSCCs). Several putative tumor suppressor genes, such as DCC, DPC4/Smad4, and MADR2/Smad2, are mapped to 18q, but thus far, the important gene locus in HNSCC is not known. To identify possible gene loci on 18q, we performed LOH studies using tumor DNA from 57 HNSCC primary tumor cell lines and DNA isolated from fibroblasts or lymphoblastoid cells from the same patients. Forty-two highly polymorphic microsatellite markers spaced not more than 5 cM apart (mean distance, 1.82 cM) spanning the region from D18S44 in 18q11.1 to D18S1141 in 18q23 were used. D18S71 in 18p11.21 on 18p was also used to determine whether the short arm was retained. Forty-three of 57 (75%) HNSCC lines showed LOH or isolated allelic imbalance (AI) for at least one locus on 18q. Although many of the cell lines had large distal 18q deletions with a breakpoint between 18q11.1 and 18q12.2 to qter, three loci were identified that were lost in 70% or more of the cases. The minimally lost regions (MLRs) range in size from 1.5-15.79 cM. The most proximal is centered on D18S39 (1.56 cM) in band 18q21.1, with LOH or isolated AI in 28 of 38 (74%) of informative cases. The largest (15.8 cM) begins at D18S61 (28 of 40; 70%) in band 18q22.2 and extends through D18S50 in 18q23. The third is centered on D18S70 (30 of 40; 75%) in band 18q23 (3.67 cM). Of these MLRs, only the one centered on D18S39 has been implicated previously in HNSCC. D18S70, the most frequently lost marker, was the only marker consistently lost in three tumor cell lines with very minimal losses, UM-SCC-19, UM-SCC-67, and UM-SCC-73A. In addition, UM-SCC-91 exhibited AI only at this locus, and UT-SCC-4 had AI at D18S70 and D18S39 only. Close physical mapping of these three regions may pinpoint one or more previously unidentified tumor suppressor genes.

Defining regions of the Y-chromosome responsible for male infertility and identification of a fourth AZF region (AZFd) by Y-chromosome microdeletion detection.

Cytogenetic and molecular deletion analyses of azoospermic and oligozoospermic males have suggested the existence of AZoospermia Factor(s) (AZF) residing in deletion intervals 5 and 6 of the human Y-chromosome and coinciding with three functional regions associated with spermatogenic failure. Nonpolymorphic microdeletions in AZF are associated with a broad spectrum of testicular phenotypes. Unfortunately, Sequence Tagged Sites (STSs) employed in screening protocols range broadly in number and mapsite and may be polymorphic. To thoroughly analyze the AZF region(s) and any correlations that may be drawn between genotype and phenotype, we describe the design of nine multiplex PCR reactions derived from analysis of 136 loci. Each multiplex contains 4-8 STS primer pairs, amplifying a total of 48 Y-linked STSs. Each multiplex consists of one positive control: either SMCX or MIC2. We screened four populations of males with these STSs. Population I consisted of 278 patients diagnosed as having significant male factor infertility: either azoospermia, severe oligozoospermia associated with hypogonadism and spermatogenic arrest or normal sperm counts associated with abnormal sperm morphology. Population II consisted of 200 unselected infertile patients. Population III consisted of 36 patients who had previously been shown to have aneuploidy, cytological deletions or translocations involving the Y-chromosome or normal karyotypes associated with severe phenotype abnormalities. Population IV consisted of 920 fertile (control) males. The deletion rates in populations I, II and III were 20.5%, 7% and 58.3%, respectively. A total of 92 patients with deletions were detected. The deletion rate in population IV was 0.87% involving 8 fertile individuals and 4 STSs which were avoided in multiplex panel construction. The ability of the nine multiplexes to detect pathology associated microdeletions is equal to or greater than screening protocols used in other studies. Furthermore, the data suggest a fourth AZF region between AZFb and AZFc, which we have termed AZFd. Patients with microdeletions restricted to AZFd may present with mild oligozoospermia or even normal sperm counts associated with abnormal sperm morphology. Though a definitive genotype/phenotype correlation does not exist, large deletions spanning multiple AZF regions or microdeletions restricted to AZFa usually result in patients with Sertoli Cell Only (SCO) or severe oligozoospermia, whereas microdeletions restricted to AZFb or AZFc can result in patients with phenotypes which range from SCO to moderate oligozoospermia. The panel of nine multiplexed reactions, the Y-deletion Detection System (YDDS), provides a fast, efficient and accurate method of assessing the integrity of the Y-chromosome. To date, this study provides the most extensive screening of a proven fertile male population in tandem with 514 infertile males, derived from three different patient selection protocols.

Microdeletions in the Y chromosome of infertile men.

BACKGROUND: Some infertile men with azoospermia or severe oligospermia have small deletions in regions of the Y chromosome. However, the frequency of such microdeletions among men with infertility in general is unknown. We sought to determine the prevalence of Y-chromosome microdeletions among infertile men and to correlate the clinical presentation of the men with specific deletions. METHODS: We studied 200 consecutive infertile men. Each man was evaluated comprehensively for known causes of infertility, and Y-chromosome microdeletions were studied with use of the polymerase chain reaction to amplify specific regions of the chromosome. The Y chromosomes of 200 normal men were also analyzed. RESULTS: Fourteen infertile men (7 percent) and four normal men (2 percent) had microdeletions of the Y chromosome. Nine of the infertile men had azoospermia or severe oligospermia (sperm concentration, <5 million per milliliter), four had oligospermia (sperm concentration, 5 million to <20 million per milliliter), and one had normospermia (sperm concentration, > or = 20 million per milliliter). The size and location of the deletions varied and did not correlate with the severity of spermatogenic failure. The fathers of six infertile men with microdeletions were studied; two had the same deletions as their sons, and four had no deletions. CONCLUSIONS: A small proportion of men with infertility have Y-chromosome microdeletions, but the size and position of the deletions correlate poorly with the severity of spermatogenic failure, and a deletion does not preclude the presence of viable sperm and possible conception.

The incidence and possible relevance of Y-linked microdeletions in babies born after intracytoplasmic sperm injection and their infertile fathers.

Microdeletions linked to deletion intervals 5 and 6 of the Y chromosome have been associated with male factor infertility. Members from at least two gene families lie in the region containing azoospermia factor (AZF), namely YRRM and DAZ. With the advent of intracytoplasmic sperm injection (ICSI), it is possible for men with severe male factor infertility to produce a child. The genetic consequences of such a procedure have been questioned. This report describes the first study of a population (32 couples) of infertile fathers and their sons born after ICSI. The objectives were firstly to determine the incidence and map location of Y chromosome microdeletions and to compare the frequencies with other population studies involving severe male factor infertility, and secondly to formulate a working hypothesis concerning developmental aetiology of Y chromosome microdeletions. The incidence of microdeletions in the ICSI population was shown to be 9.4% (within the range 9-18% reported for populations of severe male factor infertility patients). Microdeletions in two out of three affected father/son pairs mapped in the region between AZFb and AZFc and the third involved a large microdeletion in AZFb and AZFc. Of three affected father/son pairs, microdeletions were detected in the blood of one infertile propositus father and three babies. Assuming that the gonomes of the ICSI-derived babies are direct reflections of those of their fathers germ lines, it is possible that two of three infertile fathers were mosaic for intact Y and microdeleted Y chromosomes. In such cases, the developmental aetiology of the microdeletion may be due to a de-novo microdeletion arising as a post-zygotic mitotic error in the infertile propositus father, thus producing a mosaic individual who may or may not transmit the deletion to his ICSI-derived sons depending on the extent of primordial germ cell mosaicism. In one of three affected fathers, the microdeletion detected in his blood was also detected in his ICSI-derived son. In this case the de-novo event giving rise to the microdeletion may have occurred due to a post- (or pre-) meiotic error in the germ line of this father's normally fertile father (i.e. the ICSI-derived baby's grandfather).

Ascorbate as a substrate for photoproduction of hydrogen by photosystem I of chloroplasts.

The photoproduction of hydrogen by 2-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU)-inhibited chloroplasts from ascorbate under anaerobic conditions was studied in the pH range 5.0 to 7.5 using methyl viologen (MV), N,N,N',N'-tetramethyl-P-phenylenediamine (TMPD), and excess hydrogenase from Desulfovibrio desulfuricans. (a) At neutral and basic pHs, the photoreduction of MV, which reacted back with photoxidized ascorbate (dehydroascorbate [DHASC]), and the rates of H(2) photoproduction were very low. The slow H(2) photoproduction was explained by the reversible reduction of MV by the photoproduced H(2) (catalyzed by hydrogenase) and its reoxidation by DHASC resulting in H(2) uptake. (b) At pH 5.2, relatively high initial rates of H(2) photoproduction were obtained, which were comparable to the rates of O(2) consumption at pH 5.2 by photosystem I (catalyzed by photoreduced MV). However, accumulation of photoreduced MV under anaerobic conditions was not detected. In the presence of high concentrations of protons, the H(2) uptake by DHASC was very slow because the equilibrium concentration of H(2)-reduced MV was very small, thus allowing H(2) evolution mediated by photoreduced MV to compete with the back reaction with DHASC. (c) The continuous accumulation of DHASC, which was generated together with H(2), gradually slowed the H(2) evolution until it stopped after about 3 hours. At high concentrations, DHASC was able to compete with the coupling of photoreduced MV to hydrogenase and H(2) evolution. (d) Dithiothreitol (DTT) reduced the DHASC and consequently competed with the back reaction of the photoreduced and H(2)-reduced MV with DHASC. DTT thus prolonged the time period of H(2) photoproduction from ascorbate and abolished the dependence of its rate on pH in the range of 5.2 to 7.5 (e) A study of H(2) uptake by chemically oxidized ascorbate (in the dark) showed that MV and hydrogenase were both required to catalyze electron transfer from H(2) to DHASC. TMPD prevented this H(2) consumption by DHASC (in a chloroplast reaction mixture containing MV and hydrogenase). Illumination restored the H(2) uptake presumably by generating reduced MV which activated the hydrogenase.

Anomalous oxygen uptake from isolated chloroplasts inhibited in photosystem II and without external electron donors.

Light induced modulated signal of oxygen uptake by isolated chloroplasts in the presence of methyl viologen, when Photosystem II activity was inhibited and in the absence of any electron donors, was detected by a modulated oxygen Pt electrode, polarized negatively. Evidence is brought to show that an electrochemical process which takes place on the surface of the negatively polarized Pt-cathode produces an intermediate which serves as an electron donor to Photosystem I. Atempts to identify this intermediate show that it may be very probably the superoxide radical generated by the electrochemical reduction of oxygen which continuously diffuses from the external circulating medium to the electrode.

Enhancement studies on algae and isolated chloroplasts. Part II. Enhancement of oxygen evolution in intact chloroplasts.

Intact isolated chloroplasts were shown to exhibit a characteristic three-phase pattern of development of oxygen evolution activity. The first phase, Phase I, appeared to be an equilibration phase in which the isolated chloroplasts adapted to the conditions on the electrode surface. It was characterised by a rapidly increasing rate of oxygen evolution accompanied by decreasing enhancement signals. The second phase, Phase II, was an intermediate phase in which the rate of oxygen evolution was maximal and no enhancement was observed. In the last phase, Phase III, the rate of oxygen fell again, normal enhancement was still missing, but the samples appeared to undergo slow adaptive changes closely related to the State I-State II changes previously reported for whole cell systems. The concentrations of Mg2+ within the chloroplast were shown to play an important role in the control of the development of both the oxygen evolution and enhancement signals. It was shown how these signals could be explained in terms of a model that was consistent with that developed in Part I of this investigation to account for the variability of enhancement of the alga Chlorella pyrenoidosa.