In vitro inhibition of oocyte and follicular maturation and spawning in starfish (Asterias forbesi) by 2-4-dinitrophenol

The in vitro effects of 2-4-dinitrophenol (DNP) on spawning and follicular and oocyte maturation in starfish ovaries and its various cellular components were investigated. Spawning and oocyte and follicular maturation induced by starfish gonadotropin radial nerve factor (RNF) in isolated ovarian fragments were all inhibited by appropriate doses of DNP. DNP inhibits processes which occur shortly after addition of the gonadotropin; in ovarian fragments insensitivity to DNP inhibition occurred shortly after addition of RNF but prior to initiation of spawning. Spontaneous follicular and oocyte maturation which occurred following release of ovarian follicles into sea water was prevented by DNP. In non-spontaneously maturing follicles released from the ovary, DNP inhibited both follicle and oocyte maturation induced by the secondary stimulator of spawning and maturation, 1-methyladenine (1-MA). DNP also inhibited 1-MA induced meiotic maturation in isolated immature oocytes incubated in the absence of follicle cells. Inhibition of oocyte maturation was not associated with inhibition of 3H-1-MA incorporation by isolated oocytes. Immature oocytes incubated in the presence of DNP underwent maturation following washing and subsequent exposure to 1-MA. Immature oocytes initially exposed to both 1-MA and DNP, however, showed decreased maturation responsiveness following washing and re-exposure to 1-MA. The results suggest that the inhibitory effects of DNP on spawning and oocyte maturation are the result of direct effects on the oocytes and possibly other cells and tissues within the ovary.     

In vitro Inhibition of Oocyte and Follicular Maturation and Spawning in Starfish (Asterias forbesi) by 2-4-Dinitrophenol

The in vitro effects of 2-4-dinitrophenol (DNP) on spawning and follicular and oocyte maturation in starfish ovaries and its various cellular components were investigated. Spawning and oocyte and follicular maturation induced by starfish gonadotropin radial nerve factor (RNF) in isolated ovarian fragments were all inhibited by appropriate doses of DNP. DNP inhibits processes which occur shortly after addition of the gonadotropin; in ovarian fragments insensitivity to DNP inhibition occurred shortly after addition of RNF but prior to initiation of spawning. Spontaneous follicular and oocyte maturation which occurred following release of ovarian follicles into sea water was prevented by DNP. In non-spontaneously maturing follicles released from the ovary, DNP inhibited both follicle and oocyte maturation induced by the secondary stimulator of spawning and maturation, 1-methyladenine (1-MA). DNP also inhibited 1-MA induced meiotic maturation in isolated immature oocytes incubated in the absence of follicle cells. Inhibition of oocyte maturation was not associated with inhibition of ³H-1-MA incorporation by isolated oocytes. Immature oocytes incubated in the presence of DNP underwent maturation following washing and subsequent exposure to 1-MA. Immature oocytes initially exposed to both 1-MA and DNP, however, showed decreased maturation responsiveness following washing and re-exposure to 1-MA. The results suggest that the inhibitory effects of DNP on spawning and oocyte maturation are the result of direct effects on the oocytes and possibly other cells and tissues within the ovary.     

Extrafollicular mediation of oocyte maturation by radial nerve factor in starfish Pisaster ochraceus

In starfish ovaries follicle cells that envelop each oocyte are thought to mediate the production of a maturation inducing substance (MIS), identified as 1-methyladenine, that induces maturation and spawning of oocytes after exposure to a gonadotropic substance secreted by the radial nerve (RNF). Studies were carried out to assess the possible role of extrafollicular cells within the ovarian wall in mediating this signal transduction process in the ovary of Pisaster ochraceus. Oocyte maturation and spawning occurred following the addition of RNF to intact ovarian tissue in vitro whereas no maturation occurred following the addition of RNF to germinal vesicle (GV) oocytes or GV oocytes surrounded by follicle cells. In contrast, oocyte maturation occurred when small ovarian wall fragments, lacking mature follicles, were incubated with GV oocytes and RNF. Neither actinomycin D nor cycloheximide altered RNF induction of oocyte maturation in the presence of the ovarian wall tissue whereas preheating (boiling water for 5 min) the tissue obliterated its response to RNF. Non-ovarian tissues failed to produce MIS in response to RNF. Results suggest that ovarian components other than the follicle cells that envelop fully grown immature oocyte are responsive to RNF and represent a significant and previously unrecognised intra-ovarian source of MIS.     

RNA synthesis in the ovary and oocytes of the starfish

Qualitative studies on the in vitro uptake and incorporation of tritiated uridine into RNA of the somatic and germinal elements of the starfish ovary were carried out prior to and during hormone-induced oocyte maturation and spawning.Autoradiography of nonhormone-treated ovaries indicated that the outer ovarian wall contained the highest concentration of label, with lesser amounts in the follicle cells and least in the oocytes. Oocytes and follicle cells localized at the periphery of the ovary were labeled first, and both cells became progressively labeled throughout the ovary with time; the label first appeared localized in the nucleolus of the oocyte.Sucrose gradient analysis of the separated cellular components of prelabeled hormone-treated ovaries indicated that RNA synthesis occurred in all segments of the ovary and that the spawned oocyte fraction was the least active. Synthesis of ribosomal RNA was detectable after a lag period of approximately 4 hr. Oocytes incubated in ³H-uridine during and subsequent to 1-methyladenine-induced spawning and maturation synthesized 15–19 S and low molecular weight RNA but not ribosomal RNA. Synthesis of the 15–19 S RNA was inhibited with ethidium bromide and to a limited extent by actinomycin D. Isolated mitochondrial fractions contained most of the labeled 15–19 S RNA. These data suggest the mitochondrial origin of most, if not all, of this intermediate-weight RNA. On the basis of these studies, it appears that starfish oocytes and follicle cells are metabolically active at the transitional period from growth to maturational stages in oocytes. Synthesis of RNA furthermore apparently continues in the cytoplasm subsequent to germinal vesicle breakdown and spawning.     

Breakdown of starfish ovarian follicle induced by maturation-promoting factor

Immature starfish oocytes are surrounded by envelopes consisting of follicular cells. These cells adhere to each other and to the oocyte, immobilizing the latter within the ovary. When isolated oocytes in their follicles are treated with 1-methyladenine (1-MeAde), germinal vesicle breakdown (GVBD) and follicular envelope breakdown (FEBD) occur simultaneously. The 1-MeAde acts on the oocyte surface to produce a maturation-promoting factor (MPF) in the cytoplasm, which brings about GVBD. In the present study, MPF was found to induce FEBD as well as GVBD when injected into immature oocytes with their follicles in Asterina pectinifera. Although GVBD was induced by MPF in the presence of cytochalasin D, this drug prevented MPF-induced FEBD, and each follicular cell remained in situ on the surface of the oocyte. However, desmosomes connecting the processes of the follicle cell with the oocyte surface were disrupted following MPF injection even in the presence of cytochalasin D, and the processes became detached from the oocyte. FEBD occurred in these oocytes when cytochalasin D was removed, resulting in the formation of a small follicular clump by microfilament-mediated contraction of the follicle cells. These results show that FEBD is not brought about by the direct action of 1-MeAde but by the action of MPF. Therefore, in starfish, spawning as well as oocyte maturation is directly triggered by MPF produced under the influence of 1-MeAde.     

Increase in intracellular cAMP is a prerequisite signal for initiation of physiological oocyte meiotic maturation in the hydrozoan Cytaeis uchidae

In medusae of the hydrozoan Cytaeis uchidae, oocyte meiotic maturation and spawning occur as a consequence of dark-light transition. In this study, we investigated the mechanism underlying the initiation of meiotic maturation using in vitro (isolated oocytes from ovaries) and in vivo (ovarian oocytes in medusae) systems. Injection of cAMP derivatives into isolated oocytes induced meiotic maturation in a dose-dependent manner. Meiotic maturation was also achieved in isolated oocytes preloaded with caged cAMP and exposed to UV irradiation. The caged cAMP/UV irradiation-induced meiotic maturation was completely inhibited by blockers of protein kinase A (PKA), H-89, KT5720, and Rp-cAMPS. The medusae from which most parts of the umbrella were removed (umbrella-free medusae) survived for at least 2 weeks, during which time oocyte meiotic maturation and spawning occurred. When H-89 and Rp-cAMPS were injected into ovarian oocytes of umbrella-free medusae within 3 min of dark-light stimulation, meiotic maturation was inhibited or delayed. An increase in intracellular cAMP was confirmed by FlCRhR, a fluorescent cAMP indicator, in ovarian oocytes exposed to dark-light transition as well as in isolated oocytes stimulated by caged cAMP/UV irradiation. These results indicate that the cAMP/PKA signaling pathway positively contributes to light-triggered physiological oocyte meiotic maturation in Cytaeis uchidae.     

Expression of leptin and its receptor in the murine ovary: possible role in the regulation of oocyte maturation

Leptin is a product of the ob gene that is produced primarily by adipose tissue. Leptin and its receptors are found within the ovary, but it is unclear what function this hormone has in the ovary. Using immunohistochemistry, we determined that leptin is found in most cell types in the murine ovary, with the highest staining levels observed in the oocyte. Leptin receptor was also expressed in all of the main ovarian cell types, with the thecal cell layer exhibiting the highest staining levels. Leptin administration did not affect spontaneous or induced maturation of either isolated denuded oocytes or cumulus-oocyte complexes, but it did significantly increase the rate of meiotic resumption in preovulatory follicle-enclosed oocytes (P < 0.01). Measurements of cAMP within oocytes cultured with leptin showed that this enhanced ability to resume meiosis does not occur via activation of phosphodiesterase 3B and subsequent cAMP reduction. These results provide evidence that leptin affects oocyte maturation when the oocyte is cultured within its normal follicular environment. It is suggested that leptin may induce the production of another factor, possibly from thecal cells, that directly or indirectly acts on the oocyte to initiate germinal vesicle breakdown in this species.     

Comparative study of reproductive biology in single- and multiple-spawner cyprinid fish. I. Morphological and histological features

To clarify the dynamics and regulation of oogenesis in single- and multiple-spawning cyprinid fish with group-synchronous oocyte development, a multidisciplinary approach to their reproduction was undertaken using three species from the River Meuse (Belgium): the roach Rutilus rutilus as a single spawner, and the bleak Alburnus alburnus and the white bream Blicca bjoerkna as multiple spawners. The gonadosomatic index (GSI) and histomorphometric changes (distribution of oocyte size, relative proportion of the various oocyte stages) in the ovary are compared. Different patterns of GSI and oocyte growth were observed both between the single- and multiple-spawner fish and between the two multiple spawners. Maximum GSIs were higher in roach (21%) than in bleak and white bream (17.7 and 14.5%, respectively), and compared to the rapid decline of GSI in the roach population, the GSI of multiple spawners decreased progressively during the spawning season. In roach, a short gonadal quiescent period and an early onset of vitellogenesis was recorded from late summer onwards whereas, in bleak and white bream, exogenous vitellogenesis was not systematically observed before winter. A protracted spawning season and/or a low water temperature in autumn are hypothesized to explain this long period of gonadal quiescence. In bleak, during the spawning season, the oocytes recruited arose from the stock of endogenous vitellogenesis and attained the final maturation stage very rapidly. This recruitment occurred during the whole spawning season. In white bream, the differentiation of vitellogenic oocytes from smaller oocytes was completed before the onset of the spawning season. During the spawning period, the proportion of vitellogenic oocytes decreased progressively whereas the percentage of oocytes in the final maturation stage remained approximately constant.     

On gonadic maturation and reproductive strategy in deep-sea benthic octopus Graneledone macrotyla

The new information reported in this paper is based on five maturing and mature females of the large-tuberculate octopus Graneledone macrotyla. These specimens were caught in bottom trawl surveys ATLANTIS 2009 (February 24 to April 1, 2009) and ATLANTIS 2010 (March 9 to April 5, 2010) carried out off the Argentinean Economic Exclusive Zone. Capture depth ranged from 475 to 921 m and sea bottom temperature between 2.8 and 3.1 °C. Development of the complex ovary, oviducts, and oviducal glands during gonadic maturation is described. The absence of spermathecae in the oviducal glands and the presence of fertilized eggs inside the ovary suggested that fertilization took place within the ovary. Histological techniques showed the presence of four types of oocytes. Maturing oocyte size–frequency distribution was polymodal. Fluorescence reaction showed that atresia occurred in both early and later oocyte maturation stages. Atresia affected 48–55 % of the initial number of oocytes. The maximum observed potential fecundity was estimated at 250–300 eggs. G. macrotyla showed a group-synchronous ovulation pattern, regulative atresia, and a batching spawning pattern with a few egg batches spawned intermittently over an extended period of spawning.     

Surface alterations of the bovine oocyte and its investments during and after maturation and fertilization in vitro

Surface characteristics of the bovine oocyte and its investments before, during, and after maturation, and fertilization in vitro were evaluated by scanning electron microscopy (SEM). Oocyte diameters were also measured during SEM analysis of the oocyte. The cumulus cells manifested a compact structure with minimal intercellular spaces among them in the immature oocytes. These became fully expanded with increased intercellular spaces after maturation in vitro, but contracted again after fertilization. The zona pellucida (ZP) showed a fibrous, open mesh-like structure in the maturing and matured oocytes. The size and number of meshes on the ZP decreased dramatically after fertilization. The vitelline surface of immature oocytes was characterized by distribution of tongue-shaped protrusions (TSPs) varying in density. After 10 and 22 hr of maturation incubation, oocyte surface microvilli (MV) increased to become the predominant surface structure, and TSPs decreased substantially. The vitelline surface of fertilized oocytes (at 6 and 20 hr) was similar to that of the matured oocytes, but unfertilized oocytes had less dense MV than did fertilized oocytes (at 20 hr). The diameter of the oocytes decreased from 99 to 80 μm during maturation and increased to 106 μm after insemination (P < 0.05). Membrane maturation was characterized by surface changes from a TSP-predominant pattern to a MV-predominant pattern. Thus, the bovine oocyte maturation process was found to involve the expansion of cumulus cells and the maturation of the ZP, which changes dramatically upon fertilization. Also, volumetric changes occurred in ooplasm processed for SEM following oocyte maturation and insemination. © 1994 Wiley-Liss, Inc.     

银鲫卵母细胞Spindlin基因的表达特征及其功能分析

在卵母细胞成熟过程中,Spindlin与纺锤体微管蛋白相互作用,在配子到胚胎的过程中具有调节细胞周期的作用。前期研究表明,银鲫Spindlin(CagSpin)与微管蛋白相互作用,并与减数分裂的纺锤体共定位。在成熟过程中,CagSpin被磷酸化,在卵母细胞受精和卵胚转换中发挥重要的作用。研究通过对激素诱导后的卵母细胞进行追踪,采用RT-PCR和Western-blot分析,揭示卵母细胞在完成成熟的过程中,CagSpin持续大量表达。采用体外诱导卵母细胞成熟技术和显微注射的方法,揭示过量表达CagSpin导致胚泡(Germinalvesicle,GV)不能破裂,卵母细胞成熟过程被抑制。这些结果表明,CagSpin在卵母细胞成熟过程中发挥着关键的作用,同时为深入研究CagSpin的功能提供依据。     

南方鲇的繁殖生物学研究：性腺发育及周年变化

依形态学特征将南方鲇性腺的发育分为６个时期,据组织学特点将雌雄性细胞的变化各分为６个时相,幼鱼的精原细胞经历时间比卵原细胞长;发育的早期和中期,精母细胞的发育速度不同步,但到晚期则趋于同步化,３时相卵母细胞仍有卵黄核,大,小核仁数随卵母细胞的发育而变化,精孔细胞和卵胶膜源于滤泡细胞,雌雄鱼成熟年龄均为３龄,繁殖期３－５月,一次产卵类型,繁殖时不能将卵完全产出。     

Characterization and action of meiotic maturation inhibitors in starfish ovary

Mechanical release of oocytes from the ovary of the starfish Asterias amurensis into sea water results in “spontaneous” meiotic maturation of the oocytes. The substances blocking the maturation of Asterias oocytes have been purified from the ovary and shown to be steroid glycosides named asterosaponins A and B. The extract prepared from isolated oocytes was incapable of inhibiting oocyte maturation. The ovarian extract inhibited the production of 1-methyladenine (1-MA) in follicle cells surrounding the oocyte. The ovarian extract failed to influence 1-MA-induced maturation of the oocyte with or without follicle cells. It can be concluded from the present results that the role of the ovarian extract containing steroid glycosides is to arrest “spontaneous” production of 1-MA in follicle cells. The suppression can be overcome by the action of a gonadotropic peptide hormone released from the nerve tissue.     

Site of production of meiosis-inducing substance in ovary of starfish

The site of production of meiosis-inducing substance (MIS), produced in the ovary under the influence of gonad-stimulating substance (GSS) taken from radial nerves, was studied with the starfish, Asterina pectinifera. The rate of oocyte maturation observed in isolated oocytes with follicles kept in sea water containing GSS (100 μg/ml) was generally low when a small number of eggs per unit quantity of sea water was used. However, with increased number of oocytes per milliliter of GSS-sea water, the maturation rate increased up to 100% (10⁴ eggs/ml). The supernatant of such an incubation mixture of oocytes and GSS contained an appreciable amount of MIS. When a large number of oocytes (10⁴/ml) was used, the rate of oocyte maturation increased with the rise in concentration of GSS. Isolated follicles were found to produce MIS when incubated in sea water containing GSS, suggesting that the site of production of MIS is the follicle cells. The physiological role of the follicle cells surrounding the full grown oocytes seems to be to produce MIS just before spawning under the influence of GSS.     

Sexual cycle and seasonal changes in the ovary of the red mullet, Mullus surmuletus, from the southern coast of Brittany

The reproductive cycle of the red mullet is described on a macroscopic scale in terms of the GSI, HSI and K , and on a microscopic scale in terms of histological changes in the ovary and changes in the oocyte size frequency distribution. On the southern coast of Brittany the red mullet breeds in May and June. During oogenesis, the previtellogenic period lasts 6 months and the secondary phase of vitellogenesis no more than 3 months. When spawning commences the process of vitellogenesis ceases and up to 20% of the vitellogenic oocytes become atretic. Prior to spawning a single batch of oocytes can be seen to be entering secondary vitellogenesis. During the immediate prespawning and spawning periods the existing vitellogenic oocytes mature but there is no recruitment from the stock of previteilogenic oocytes. This results in a gap or hiatus in the oocyte size frequency distribution between previtellogenic and vitellogenic oocytes within which there are very few resting or maturing oocytes. The red mullet appears to be a determinate spawner, in which egg loss through atresia considerably reduces the potential fecundity.     

Inhibitory effect of a SALMFamide neuropeptide on secretion of gonad-stimulating substance from radial nerves in the starfish Asterina pectinifera

In starfish, the peptide hormone gonad-stimulating substance (GSS) secreted from nervous tissue stimulates oocyte maturation to induce 1-methyladenine (1-MeAde) production by ovarian follicle cells. The SALMFamide family is also known to an echinoderm neuropeptide. The present study examined effect of SALMFamide 1 (S1) on oocyte maturation of starfish Asterina pectinifera. Unlike GSS, S1 did not induce spawning in starfish ovary. In contrast, S1 was found to inhibit GSS secretion from radial nerves by treatment with high K+ concentration. Fifty percent inhibition was obtained by 0.1 mM S1. S1 did not have any effect on GSS- and 1-MeAde-induced oocyte maturation. Following incubation with a S1 antibody and subsequently with rhodamine-conjugated second antibody, neural networks were observed in ovaries. The networks were restricted mainly to their surface with little evidence of immunoreactivity inside the basement membranes. This indicates that neural networks are distributed in the ovarian wall. The result further suggests that S1 plays a role in oocyte maturation to regulate GSS secretion from the nervous system.     

Stereological assessment of the reproductive status of female Atlantic northern bluefin tuna during migration to Mediterranean spawning grounds through the Strait of Gibraltar

The ovarian mass and gonadosomatic index (I_G) of bluefin tuna Thunnus thynnus , caught in the Strait of Gibraltar (Barbate) during migration to Mediterranean spawning grounds, were several times lower than those found in bluefin tuna from Mediterranean spawning grounds (Balearic Islands). Some of the bluefin tuna from Barbate (8.3%) were classified as immature (the most advanced oocytes present in the ovaries were early vitellogenic), and the majority (the remaining 91.6%) as non-spawning mature; the ovary contained late vitellogenic oocytes, but there was no sign of spawning activity. Stereological estimation indicated that the ovaries of spawning bluefin tuna from the Balearic Islands contained five-fold more highly yolked oocytes than bluefin tuna from Barbate. When breeding bluefin tuna cross the Strait of Gibraltar the gonad is at an incipient stage of maturation. The average batch fecundity estimated from stereological quantification of stage 4 (migratory-nucleus) oocytes in the specimens collected from Balearic was 92.8 oocytes g-1'of body mass, and the spawning frequency in this area was calculated to be 1.2 days. In specimens from Barbate a relative batch fecundity of 96.3 oocytes g -1 was estimated using stage 3 (late vitellogenic) oocyte counts.     

卵母细胞在哺乳动物卵巢排卵过程中的决定性作用

哺乳动物卵巢排卵是一个复杂的调控过程。卵泡成熟破裂后,卵母细胞从卵巢中排出。卵泡细胞感受排卵刺激,并诱导卵母细胞减数分裂的恢复及其随后的释放。卵母细胞及其周围颗粒细胞的旁分泌在对此起关键性作用,其中卵母细胞对其释放具有决定性作用。作者先前已经阐述过颗粒细胞在哺乳动物卵巢排卵过程中的调控作用,该文将从卵母细胞的发育及其调控角度重点阐明其在排卵过程中的决定作用,旨在进一步理解哺乳动物卵巢的排卵过程,同时为不孕不育等卵巢疾病的治疗提供重要的研究方向和理论基础。     

A complex cortical reaction leads to formation of the fertilization envelope in the lobster,Homarus

We have examined the formation of the fertilization envelope in the lobsters Homarus americanus and H gammarus. Oocytes were fixed for electron microscopy either in the ovary or following extrusion from the gonopore. Mature ovarian oocytes are surrounded by a coat (envelope 1), which is comprised of small electron-dense granules and structures resembling “bottlebrushes.” At least part of this coat is synthesized by the follicle cells of the ovary. The cortex of ovarian oocytes contains four types of vesicles that we refer to as high-density vesicles (HDV), low-density vesicles (LDV), moderately dense vesicles (MDV), and ring vesicles (RV). Oocytes that were electrically extruded from the gonopore and fixed immediately had an envelope identical to that of ovarian oocytes. The cortex of gonopore oocytes contained the four types of vesicles found in ovarian oocytes. When unfertilized gonopore oocytes were allowed to incubate in sea water, the oocyte cortex appeared unaltered, but envelope 1 swelled and the bottlebrushes dispersed. When recently fertilized oocytes were fixed during natural spawning or following in-vitro fertilization, each type of vesicle was released in sequence from the cortex of the oocyte. The contents of the HDV and LDV appeared first in the perivitelline space, but their fate could not be determined at later times. The ring-shaped elements of the RV and the moderately electron-dense material of the MDV were released exocytotically somewhat later; these materials coalesced in the perivitelline space to form a new coat (envelope 2). Envelope 1 subsequently condensed to its original thickness and appeared firmly attached to envelope 2. Our results show that the fertilized lobster egg is surrounded by two discrete coats. The outer coat, which is formed in the ovary, undergoes a swelling/condensation cycle at spawning. The inner coat originates from a complex cortical reaction. Together these coats comprise the fertilization envelope of the lobster egg.     

Possible MIS Production by Follicle Cells in Spontaneous Oocyte Maturation of the Ascidian, Halocynthia roretzi

Outer and inner follicle cell-enclosed oocytes (oocyte complexes) of Halocynthia roretzi underwent germinal vesicle breakdown (GVBD) within 2 hr when transferred from ovaries to normal seawater of pH 8 (NSW). Extrusion of test cells (TC) into the perivitelline space and elevation of the chorion also occurred. This phenomenon was designated as spontaneous oocyte maturation.
Seawater of low pH, protease inhibitors such as leupeptin or soybean trypsin inhibitor (SBTI), and calcium deficiency inhibited the spontaneous maturation only when introduced to the NSW during the first 10 minutes of incubation. GVBD-blocked complexes underwent GVBD after addition of trypsin regardless of pH or the absence of calcium ions. The oocytes from which follicle cells were removed with glycosidase did not undergo GVBD in NSW, but addition of trypsin triggered GVBD in these defolliculated oocytes (TC oocytes). Furthermore, incubation media in which spontaneous maturation had occurred, induced GVBD in the TC oocytes. This GVBD-inducing activity was heat-labile and was inhibited by leupeptin.
These results indicate that in the first step of the spontaneous oocyte maturation, outer and/or inner follicle cells give a signal to the oocyte itself or TC oocyte. This signal is likely to be trypsin-like.