Cytoskeletal Development In The Epidermal Cells Of An Insect, Calpodes Ethlius Stoll (lepidoptera:hesperiidae)

A basic problem in insect metamorphosis is the means by which insects change shape. This can be studied by examining the shape changes of individual epidermal cells. I have found that removal of the basal lamina from the epidermis allows the shape and basal surfaces of these cells to be seen by scanning electron microscopy. In the 5th larval stage of Calpodes ethlius the cells extend basal processes or feet. Feet develop in three phases. Just after ecdysis they are short and randomly oriented. The cells are closely packed and their bases have punctate hemidesmosomes. The hemidesmosomes become elongated and axially oriented before commitment to pupation. The feet then also extend, and orient axially. The feet contract late in the stadium, disappearing as the cells move to their pupal positions. This cell rearrangement is facilitated by the formation of wide intercellular lymph spaces. Filopodia span and presumably aid closure of the spaces between the cells at pupation. The changes in the feet suggest that they are prime movers in epidermal morphogenesis.;The disposition of the cytoskeleton is related to the control of cell shape. For example, orientation of the feet may be controlled by selective stabilization of dynamically unstable microtubules. My work on epidermal cells suggests that cytoskeletal shape may also be influenced by somatic inheritance. The cells contain apical bundles of F-actin (shown using rhodaminyl phalloin labeling) which survive for about 36 hours after the 4th-5th larval ecdysis and associate with a transverse cuticle component. The number of bundles is paired in adjacent cells which are presumed to be siblings. The maintenance of cytoplasmic continuity through midbodies connecting siblings may preserve the paired patterns. These patterns are a result of sibling similarity, either in ploidy or by the inheritance of transient determinants for bundle pattern and position.;I have found that the secretory cell of the dermal gland is another epidermal cell whose shape is partly determined by the arrangement of its microfilament skeleton. The cell is distended during the intermoult by accumulation of secretion in vacuoles encapsulated by F-actin. At ecdysis the microfilament capsules collapse while the secretion is discharged and the cell shrivels. The microfilaments form into storage bundles which are then redistributed into capsules. This cycle repeats in each stadium until the cell atrophies in the pupa

How common is germinal mosaicism that leads to premeiotic aneuploidy in the female?

PURPOSE: Molecular cytogenetic analysis has confirmed that a proportion of apparently meiotic aneuploidy may be present in the germ cells prior to the onset of meiosis, but there is no clear perception of its frequency. The aim of this review is to assess the evidence for premeiotic aneuploidy from a variety of sources to arrive at an estimate of its overall contribution to oocyte aneuploidy in humans. METHODS: Relevant scientific literature was covered from 1985 to 2018 by searching PubMed databases with search terms: gonadal/germinal mosaicism, ovarian mosaicism, premeiotic aneuploidy, meiosis and trisomy 21. Additionally, a key reference from 1966 was included. RESULTS: Data from over 9000 cases of Down syndrome showed a bimodal maternal age distribution curve, indicating two overlapping distributions. One of these matched the pattern for the control population, with a peak at about 28 years and included all cases that had occurred independently of maternal age, including those due to germinal mosaicism, about 40% of the cohort. The first cytological proof of germinal mosaicism was obtained by fluorescence in situ hybridisation analysis. Comparative genomic hybridisation analysis of oocyte chromosomes suggests an incidence of up to 15% in premeiotic oocytes. Direct investigation of fetal ovarian cells led to variable results for chromosome 21 mosaicism. CONCLUSIONS: Oocytes with premeiotic errors will significantly contribute to the high level of preimplantation and prenatal death. Data so far available suggests that, depending upon the maternal age, up to 40% of aneuploidy that is present in oocytes at the end of meiosis I may be due to germinal mosaicism

Meiotic outcome in two carriers of Y autosome reciprocal translocations: selective elimination of certain segregants

BACKGROUND: Reciprocal Y autosome translocations are rare but frequently associated with male infertility. We report on the meiotic outcome in embryos fathered by two males with the karyotypes 46,X,t(Y;4)(q12;p15.32) and 46,X,t(Y;16)(q12;q13). The two couples underwent preimplantation genetic diagnosis (PGD) enabling determination of the segregation types that were compatible with fertilization and preimplantation embryo development. Both PGD and follow up analysis were carried out via fluorescence in situ hybridization (FISH) or array comparative genomic hybridization (aCGH) allowing the meiotic segregation types to be determined in a total of 27 embryos. RESULTS: Interestingly, it was seen that the number of female embryos resulting from alternate segregation with the chromosome combination of X and the autosome from the carrier gamete differed from the corresponding balanced males with derivative Y and the derivative autosome by a ratio of 7:1 in each case (P = 0.003) while from the adjacent-1 mode of segregation, the unbalanced male embryos with the combination of der Y and the autosome were seen in all embryos from couple A and in couple B with the exception of one embryo only that had the other chromosome combination of X and derivative autosome (P = 0.011). In both cases the deficit groups have in common the der autosome chromosome that includes the segment Yq12 to qter. CONCLUSION: The most likely explanation may be that this chromosome is associated with the X chromosome at PAR2 (pseudoautosomal region 2) in the sex-body leading to inactivation of genes on the autosomal segment that are required for the meiotic process and that this has led to degeneration of this class of spermatocytes during meiosis

The impact of mosaicism in preimplantation genetic diagnosis (PGD): approaches to PGD for dominant disorders in couples without family history

OBJECTIVES: Mosaicism in certain dominant disorders may result in a 'non-Mendelian' transmission for the causative mutation. Preimplantation genetic diagnosis (PGD) is available for patients with inherited disorders to achieve an unaffected pregnancy. We present our experience for two female patients with different dominantly inherited autosomal disorders; neurofibromatosis type 1 (NF1) and tuberous sclerosis complex type 2 (TSC2). METHODS: PGD protocol development was carried out using single cells from the patients. PGD was carried out on polar bodies and different embryonic cells. RESULTS: Protocol development for NF1 using lymphocytes from the patient suggested mosaicism for the mutation. This was supported further by quantitative fluorescent-PCR performed on genomic DNA. During PGD, polar bodies and blastomeres lacked the mutation that probably was absent or present at very low levels in the patient's germline. Single lymphocyte analysis during protocol development for TSC2 did not indicate mosaicism; however, analysis of single buccal cells and multiple embryo biopsies across two consecutive IVF/PGD cycles confirmed gonosomal mosaicism. CONCLUSIONS: The trend in PGD is for blastocyst biopsy followed by whole genome amplification, eliminating single cell analysis. In the case of certain dominantly inherited disorders, pre-PGD single cell analysis is beneficial to identify potential mosaicism that ensures robust protocols. © 2016 John Wiley & Sons, Ltd

The origin and significance of additional aneuploidy events in couples undergoing preimplantation genetic diagnosis for translocations by array comparative genomic hybridization

Diagnostic application of array comparative genomic hybridization (aCGH) in preimplantation genetic diagnosis for reciprocal and Robertsonian translocations has revealed 55–65% embryos with additional aneuploidies with or without translocation-related imbalances. The occurrence of these extra abnormalities with the balanced form of the translocation reduces the number of embryos suitable for transfer. Eighty-three embryos were followed up on days 5–7 of development from 23 infertile or sub-fertile carriers for whole chromosome and segmental aneuploidies present in addition to the balanced or unbalanced translocations detected on aCGH diagnosis. Embryos were analysed by fluorescence in-situ hybridization (n = 63) and aCGH (n = 20). Meiotic aneuploidy affected 35% of embryos and 47% had mitotic events; 15% had both types. Meiotic and mitotic events were almost equal (60 versus 64), 97 affected whole chromosomes (58 meiotic, 39 mitotic) and 27 were segmental (two meiotic, 25 mitotic). In 85.5% of embryos with whole chromosome additional aneuploidies, the aneuploidy was present throughout or in more than 50% of cells. All embryos diagnosed as abnormal (translocation balanced or unbalanced) after aCGH diagnosis at cleavage stage would have remained unsuitable for transfer if tested at later stages of development. Additional aneuploidies merit full consideration when considering the choice of embryos to transfer

Meiotic and mitotic behaviour of a ring/deleted chromosome 22 in human embryos determined by preimplantation genetic diagnosis for a maternal carrier

<p>Abstract</p> <p>Background</p> <p>Ring chromosomes are normally associated with developmental anomalies and are rarely inherited. An exception to this rule is provided by deletion/ring cases. We were provided with a unique opportunity to investigate the meiotic segregation at oogenesis in a woman who is a carrier of a deleted/ring 22 chromosome. The couple requested preimplantation genetic diagnosis (PGD) following the birth of a son with a mosaic karyotype.</p> <p>The couple underwent two cycles of PGD. Studies were performed on lymphocytes, single embryonic cells removed from 3 day-old embryos and un-transferred embryos. Analysis was carried out using fluorescence in situ hybridisation (FISH) with specific probe sets in two rounds of hybridization.</p> <p>Results</p> <p>In total, 12 embryos were biopsied, and follow up information was obtained for 10 embryos. No embryos were completely normal or balanced for chromosome 22 by day 5. There was only one embryo diagnosed as balanced of 12 biopsied but that accumulated postzygotic errors by day 5. Three oocytes apparently had a balanced chromosome 22 complement but all had the deleted and the ring 22 and not the intact chromosome 22. After fertilisation all the embryos accumulated postzygotic errors for chromosome 22.</p> <p>Conclusion</p> <p>The study of the preimplantation embryos in this case provided a rare and significant chance to study and understand the phenomena associated with this unusual type of anomaly during meiosis and in the earliest stages of development. It is the first reported PGD attempt for a ring chromosome abnormality.</p

Errors in chromosome segregation during oogenesis and early embryogenesis

Errors in chromosome segregation occurring during human oogenesis and early embryogenesis are very common. Meiotic chromosome development during oogenesis is subdivided into three distinct phases. The crucial events, including meiotic chromosome pairing and recombination, take place from around 11 weeks until birth. Oogenesis is then arrested until ovulation, when the first meiotic division takes place, with the second meiotic division not completed until after fertilization. It is generally accepted that most aneuploid fetal conditions, such as trisomy 21 Down syndrome, are due to maternal chromosome segregation errors. The underlying reasons are not yet fully understood. It is also clear that superimposed on the maternal meiotic chromosome segregation errors, there are a large number of mitotic errors taking place post-zygotically during the first few cell divisions in the embryo. In this chapter, we summarise current knowledge of errors in chromosome segregation during oogenesis and early embryogenesis, with special reference to the clinical implications for successful assisted reproduction

Human guanylate kinase (GUK1): cDNA sequence, expression and chromosomal localisation

AbstractGuanylate kinase (GK) catalyses the conversion of GMP to GTP as part of the cGMP cycle. In mammalian phototransduction, this cycle is essential for the regeneration of cGMP following its hydrolysis by phosphodiesterase. Mutations in different parts of this signalling cascade lead to retinal degeneration in humans. Protein studies have localized a locus for GK to a region of human chromosome 1 that also contains an autosomal recessive form of retinitis pigmentosa (RP12) and Usher's type 11a (USH2A). We report the sequence of this human GK (GUK1) and a further refinement of its localization to 1q32-41, placing it in the same interval as USH2A