@phdthesis{Pasch2016,
  author    = {Pasch, Elisabeth},
  title     = {The role of SUN4 and related proteins in sperm head formation and fertility},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-139092},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Spermiogenesis describes the differentiation of haploid germ cells into motile, fertilization-competent spermatozoa. During this fundamental transition the species-specific sperm head is formed, which necessitates profound nuclear restructuring coincident with the assembly of sperm-specific structures and chromatin compaction. In the case of the mouse, it is characterized by reshaping of the early round spermatid nucleus into an elongated sickle-shaped sperm head. This tremendous shape change requires the transduction of cytoskeletal forces onto the nuclear envelope (NE) or even further into the nuclear interior. LINC (linkers of nucleoskeleton and cytoskeleton) complexes might be involved in this process, due to their general function in bridging the NE and thereby physically connecting the nucleus to the peripheral cytoskeleton. LINC complexes consist of inner nuclear membrane integral SUN-domain proteins and outer nuclear membrane KASH-domain counterparts. SUN- and KASH-domain proteins are directly connected to each other within the perinuclear space, and are thus capable of transferring forces across the NE. To date, these protein complexes are known for their essential functions in nuclear migration, anchoring and positioning of the nucleus, and even for chromosome movements and the maintenance of cell polarity and nuclear shape. In this study LINC complexes were investigated with regard to their potential role in sperm head formation, in order to gain further insight into the processes occurring during spermiogenesis. To this end, the behavior and function of the testis-specific SUN4 protein was studied. The SUN-domain protein SUN4, which had received limited characterization prior to this work, was found to be exclusively expressed in haploid stages during germ cell development. In these cell stages, it specifically localized to the posterior NE at regions decorated by the manchette, a spermatid-specific structure which was previously shown to be involved in nuclear shaping. Mice deficient for SUN4 exhibited severely disorganized manchette residues and gravely misshapen sperm heads. These defects resulted in a globozoospermia-like phenotype and male mice infertility. Therefore, SUN4 was not only found to be mandatory for the correct assembly and anchorage of the manchette, but also for the correct localization of SUN3 and Nesprin1, as well as of other NE components. Interaction studies revealed that SUN4 had the potential to interact with SUN3, Nesprin1, and itself, and as such is likely to build functional LINC complexes that anchor the manchette and transfer cytoskeletal forces onto the nucleus. Taken together, the severe impact of SUN4 deficiency on the nucleocytoplasmic junction during sperm development provided direct evidence for a crucial role of SUN4 and other LINC complex components in mammalian sperm head formation and fertility.},
  subject      = {Maus},
  language  = {en}
}
@phdthesis{Link2013,
  author    = {Link, Jana},
  title     = {The role of meiotic nuclear envelope components in chromosome dynamics and meiotic progression},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-83540},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2013},
  abstract  = {Meiosis is the specialised cell division which produces haploid germ cells, capable of developing into fertile gametes, from diploid progenitor cells. During meiosis, chromosomes undergo strictly regulated and strongly conserved dynamic processes, at the beginning of which the telomeres are actively tethered and intimately attached to the nuclear envelope (NE). The attached telomeres are then moved within the NE through cytoskeletal forces to cluster within a restricted region, forming the highly conserved bouquet stage. Subsequently, the bouquet is released simultaneously to the completion of the synaptonemal complex assembly tightly linking homologous chromosome pairs together. In combination these processes are essential for the successful completion of meiosis. Because the meiotic NE serves as a platform for telomere attachment and movement it can be assumed to be critically involved in these events crucial for fertility. However, the precise roles of many meiotic NE proteins in the attachment and movement of telomeres still remain elusive. Therefore, it was the aim of this thesis to investigate the functions of two mammalian meiotic NE components in telomere attachment and dynamics. The first part of this thesis is concerned with the meiosis-specific lamin C2. Lamin C2 is the only A-type lamin expressed during meiosis and has in previous studies shown to feature altered meiosis-specific properties, clearly distinguishing it from somatic lamins. Because lamin C2 is enriched at sites of telomere attachment, exhibits a high mobility within the nuclear lamina and influences NE integrity, it has been postulated that it may locally increase NE flexibility to allow efficient meiotic telomere movement. Therefore, possible functions of lamin C2 in the movement of attached telomeres were investigated in this thesis by studying the bouquet formation and release of pubertal mice specifically lacking lamin C2. This revealed that lamin C2 deficient mice show a delayed bouquet release, leading to severe defects in the synaptic pairing of homologous chromosomes, which in turn results in infertility of the males. Therefore, the efficient repositioning of attached meiotic telomeres, facilitated by lamin C2, seems essential for completing meiosis. The second part of this thesis focuses on the protein complex responsible for the attachment of meiotic telomeres to the NE and their coupling to the cytoskeleton. The so-called LINC complex is composed of SUN domain proteins in the inner nuclear membrane interacting with KASH domain proteins of the outer nuclear membrane. In previous studies it had been shown that SUN1, SUN2 and KASH5 localise to the attached meiotic telomeres. Regarding the meiotic role of SUN2, however, contradicting results have recently been discussed, showing the need for further investigations. Using an available SUN1 deficient mouse strain, this thesis was able to show that SUN2 is sufficient for telomere attachment per se although telomere attachment is impaired in SUN1 deficient mice leading to infertility. It is also demonstrated that SUN2 forms a functional LINC complex together with KASH5 to mediate this telomere attachment. This LINC complex in the absence of SUN1 is able to move attached telomeres into a bouquet-like cluster formation. Therefore, this demonstrates that SUN2 is involved in the functional attachment and movement of meiotic telomeres. In summary, this thesis has shown SUN2 and the meiotic nuclear lamina to be directly involved in or essential for the highly conserved attachment and movement of telomeres, making them critical for a successful meiosis. The meiotic NE is therefore in this thesis demonstrated to be a determinant of mammalian fertility.},
  subject      = {Meiose},
  language  = {en}
}