鹤顶兰胚囊发育过程中微管变化的共焦显微镜观察

光镜的观察确定了鹤顶兰（Ｐｈａｉｕｓ ｔａｎｋｅｒｖｉｌｌｉａｅ （Ａｉｔｏｎ） Ｂｌ．）胚囊发育属单孢子蓼型。应用免疫荧光标记技术及共焦镜观察了胚囊发育过程中微管分布的变化。当孢原细胞初形成时,细胞内的微管呈网状分布。之后,孢原细胞体积增大发育为大孢子母细胞。大孢子母细胞延长,进入减数分裂Ⅰ。微管由分裂前的网状分布变为辐射状排列。二分体的两个细胞内的微管分布一样,呈辐射状。四分体的近珠孔端的３ 个大孢子解体,细胞内的微管消失。靠合点端的功能大孢子内有许多微管呈网状分布。当功能大孢子进入第一次有丝分裂时,细胞内的微管由网状变为辐射状,从核膜伸展至周质。再经两次有丝分裂形成八核胚囊。在核分裂之前微管一般是呈网状分布并紧包围着核。在分裂期间二核和四核胚囊都呈极性现象,微管系统也呈极性分布。微管在八核胚囊内的分布变化情形特别复杂。首先,八核分别作不同程度的移动,其中两个核移向胚囊中央,珠孔端和合点端的３ 个核分别互相靠拢,形成３ 个区,即中央区、反足区和卵器区。胚囊未形成区时,８ 个核都被网状分布的微管包围着。当胚囊明显分成区时,反足区内的微管仍作网状分布。中央区的微管分布则趋疏松,形成篮形结构,包围着液泡和两个极核。在     

Confocal Microscopic Observations on Microtubular Cytoskeleton Changes During Megasporogenesis and Megagametogenesis in Phaius tankervilliae (Aiton) Bl.

In nun orchid (Phaius tankervilliae (Alton) B1. ) embryo sac development follows the monosporic pattern. Changes in the pattern of organization of the microtubular cytoskeleton during megasporogenesis and megagametogenesis in this orchid were studied using the immunofluorescence technique and eonfocal microscopy. At the initial stage of development the microtubules in the arehesporium were randomly oriented into a network. Later the archesporial cell elongated to form the megasporocyte. The cytoskeleton in the elongated megasporoeyte was radially organized in which microtubules extending from the nuclear envelope to the peripheral region of the cell. The megasporoeyte then underwent meiosis 1 to form a dyad. The dyad cell at the chalazal end was larger than the cell at the micropylar end. Microtubules in the dyad cell were radially oriented. The dyad underwent meiosis to give rise to a linear array of four megaspores (i. e. tetrad formation). The chalazal-far most megaspore survived and became the functional megaspore, which contained a set of randomly oriented microtubules. The microtubules in the other 3 megaspore disappeared as the cells degenerated. The functional megaspore then underwent mitotic division giveing rise to a 2 nucleate embryo sac. The nuclei of the 2-nucleate embryo sac were separated by a set of longitudinally oriented microtubules which ran parallel to the long axis of the embryo sac. Each nucleus in the embryo sac was surrounded by a set of perinuelear microtubules. The gnucleate embryo sac again underwent mitotic division to form a 4-nucleate embryo sac. The division of the two nuclei was synchronous. But the orientation of the division plan of the two spindles was different (i. e. the spindle microtubules at the chalazal end ran parallel with the long axis of the embryo sac and those at the mieropylar end ran at right angle to the axis of the embryo sac). The 4 nuclei of the 4-nucleate embryo sac were all tightly surrounded by randomly oriented microtubules. Later the paired nuclei at the micropylr end and at the chalazal end as well underwent mitotic division in seguence. At this time when the embryo sac had reached the 8-nucleate embryo sac stage. The pattern of organization of the microtubules was very complex. Initially the nuclei were surrounded by a set of randomly oriented microtubules, but after the two polar nuclei had moved to the central region of the embryo sac, three different organizational zones of microtubules appeared, viz: a randomly oriented set of microtubules surrounding each nucleus in the chalazal zone: a set (in the form of a basket) of cortical microtubules which surrounded the vacuoles and the two polar nuclei in the central zone and a loosely knitted network of microtubules surrounding the nucleus that later became the egg cell nucleus in the micropylar zone. The two nuclei that would become the nuclei of the synergids were surrounded by a set of more densely packed mierotubules. Towards far the most micropylar end some microtubules formed thick bundles. The site of appearance of these thick bundles coincided with the site of development of the filiform apparatus. The pattern of microtubule organization after cellularization (i. e. at the beginning of embryo sac maturation) did not change much. The author's results indicated that various patterns of microtubule organization observed in the developing embryo sac of nun orchid reflected the complexity and dynamism of the embryo sac.     

利用激光扫描共聚焦显微术对同源四倍体水稻胚囊形成与发育的进一步观察

应用改进的整体染色透明激光扫描共聚焦显微术(WCLSM),对同源四倍体水稻PDER-2B-4x胚囊的形成与发育过程进行观察。发现其胚囊的形成发育过程与二倍体的一致,可以清楚地划分为8个发育时期,即孢原细胞形成期、大孢子母细胞形成期、大孢子母细胞减数分裂期、功能大孢子形成期、单核胚囊形成期、胚囊有丝分裂期、八核胚囊发育期和成熟胚囊期。除正常发育的过程外,大孢子发育的各个过程均出现一些异常现象,包括:细胞退化、核位置异常、核数目异常和细胞分化异常等。这些异常可能最终导致多种结构异常成熟胚囊的形成。     

Origin of Megagametophytes with Supernumerary Egg Cells Occurring in Oryza sativa

Cytoembryological observations were attempted to reveal the cytological origin of megagametophyte with supernumerary egg cells. It was shown that all ovules underwent a normal megasporogenesis. The meiosis of megasporocyte consisted of two successive divisions, which gave rise to four haploid megaspores. It was the chalazal spore that developed to form the megagametophyte while the three micropylar megaspores degenerated quickly. After first mitosis in the functional megaspore the two nuclei were separated to the micropylar and chalazal poles by a large central vacuole, meanwhile a differential enlargement of the two-nucleate embryo sac was visualized. The micropylar side enlarged quickly and in contrast, the chalazal side remains almost unchanged. Immediately afterward, the second mitosis took place forming four-nucleate embryo sac. During the second mitosis, nucleus located in the narrow area of chalazal side divided transversely, with its upper sister nucleus migrating to the central or micropylar part of the embryo sac, while the nucleus in the micropylar side divided at an angle of about 45° against the micropylar-chalazal axis. Through the third mitosis, two patterns of nuclear arrangement deviating from polygonum were observed. (i) One nuclear distribution pattern was two, two, four respectively in chalazal, central and micropylar parts. And during maturation the four micropylar nuclei differentiated as egg apparatus consisting of two egg cells and two synergids. The two central nuclei, which presumably suppressed the movement of nucleus toward centre part from both micropylar and chalazal sides developed into central cell with two polar nuclei. And the two chalazal nuclei organized into antipodal cells. Rarely indeed, one nucleus of either chalazal or micropyle side did migrate to join the formation of central cell. (ii) The other nuclei arrangement pattern was two and six respectively positioned in chalazal and micropylar sides. During maturation, five micropylar nuclei differentiated into egg apparatus consisted of three egg cells and two synergids. The sixth one migrated to form the upper polar nucleus. The lower nucleus of the chalazal side developed into antipodal cell which divided quickly, and the upper nucleus became the lower polar nucleus.     

The microtubular cytoskeleton during megasporogenesis in the Nun orchid, Phaius tankervilliae

This study examines the microtubular cytoskeleton during megasporogenesis in the Nun orchid, Phaius tankervilliae . The subepidermal cell located at the terminal end of the nucellar filament differentiates first into an archesporial cell and then enlarges to become the megasporocyte. The megasporocyte undergoes the first meiotic division, giving rise to two dyad cells of unequal size. Immunostaining reveals that microtubules become more abundant as the megasporocyte increases in size. Microtubules congregate around the nucleus forming a distinct perinuclear array and many microtubules radiate directly from the nuclear envelope. In the megasporocyte, prominent microtubules are readily detected at the chalazal end of the cell cytoplasm. After meiosis I, the chalazal dyad cell expands in size at the expense of the micropylar dyad cell. At this stage, new microtubule organizing centres can be found at the corners of the cells. The appearance of these structures is stage-specific and they are not found at any other stages of megasporogenesis. The functional dyad cell undergoes the second meiotic division, resulting in the formation of two megaspores of unequal size. The chalazal megaspore enlarges and eventually gives rise to the embryo sac. As the functional megaspore expands, the microtubules again form a distinct perinuclear array with many microtubules radiating from the nuclear envelope. A defined cortical array of microtubules has not been found in P. tankervilliae during the course of megasporogenesis.     

Embryo Sac Development in the Maize indeterminate gametophyte1 Mutant: Abnormal Nuclear Behavior and Defective Microtubule Organization

The indeterminate gametophyte1 mutation in maize has been known to disrupt development of the female gametophyte. Mutant embryo sacs have abnormal numbers and behavior of micropylar and central cell nuclei, which result in polyembryony and elevated ploidy levels in the endosperm of developing kernels. In this study, we confirm abnormal nuclear behavior and present novel findings. In contrast to the normal form, there is no obvious polarity in two-nucleate embryo sacs or in the micropylar cells of eight-nucleate embryo sacs. We show that the second and third mitoses are not fully synchronized and that additional mitoses can occur in all of the nuclei of the mutant embryo sac or in just the micropylar or central regions. After cellularization, individual micropylar cells can undergo mitosis. Abnormal microtubular behavior results in irregular positioning of the nuclei, asynchronous microtubular patterns in different pairs of nuclei, and abnormal phragmoplasts after the third mitotic division. These results indicate that in addition to acting primarily in controlling nuclear divisions, the indeterminate gametophyte1 gene acts secondarily in regulating microtubule behavior. This cytoskeletal activity most likely controls the polarization and nuclear migration underlying the formation and fate of the cells of the normal embryo sac.     

水稻胚囊发育过程中微管的变化

对水稻(Oryza sativa L.)胚囊发育过程中微管变化的研究表明,微管在胚囊发育的不同阶段变化多样。在大孢子母细胞阶段微管分布主要呈辐射状,部分纵向排列。二分体和功能大孢子具类似的微管分布,而在单核胚囊微管主要是随机分布,部分呈辐射状。两核和四核胚囊的微管组成和分布非常相似,主要分布于细胞核周围。而八核胚囊的微管分布较为复杂,胚囊中的细胞做管分布各异,在卵细胞中呈随机分布,在助细胞中大多数呈纵向分布,而在中央细胞中呈横向分布,微管在反足细胞中非常分散,细胞质中有少量纵向排列的微管。     

Mitosis in the free-living flagellate Bodo saltans strain PS+ (Kinetoplastidea, Bodonida)

The mitosis in the free-living flagellate Bodo saltans Ps+ with prokaryotic cytobionts in perinuclear space has been studied. The nuclear division in B. saltans Ps+ occurs by closed mitosis type without condensation of chromosomes. Two spatially separated mitotic spindles begin to form consistently at the initial stages of nuclear division. The spindle including about 20 microtubules appears first and later the second spindle with half the number of microtubules comes at the angle of 30-40 degrees. Both spindles rest their ends against the inner nuclear membrane and form 4 distinct poles. The microtubules of the first spindle are associated with 4 pairs of kinetochores, the microtubules of the second one are associated with 2 pairs of kinetochores. The divergence of the kinetochores towards the poles occurs independently in each spindle. The equatorial phase is not revealed in B. saltans Ps+. The poles of both spindles unite in pairs at the elongation phase of mitosis and form the integrated bipolar structure. At this stage of the nuclear division, the kinetochores reach the poles of subspindles and become indistinguishable. Then the nucleus takes the shape of a dumbbell. The inner nuclear membranes of just formed nuclei have layers of condensed chromatin characteristic of the interphase nuclei of kinetoplastidea. The daughter nuclei separate at the phase of reorganization. There are 1-2 prokaryotic endocytobionts in the perinuclear space of the interphase nuclei in B. saltans Ps+. The symbionts multiply during mitosis and their number reaches more than 20 specimens par nucleus.     

Development of the endosperm in rice (Oryza sativa L.): Cellularization

The syncytial endosperm of rice undergoes cellularization according to a regular morphogenetic plan. At 3 days after pollination (dap) mitosis in the peripheral synctium ceases. Radial systems of microtubules emanating from interphase nuclei define nuclear-cytoplasmic domains (NCDs) which develop axes perpendicular, to the embryo sac wall. Free-growing anticlinal walls between adjacent NCDs compart-mentalize the cytoplasm into open-ended alveoli which are overtopped by syncytial cytoplasm adjacent to the central vacuole. At 4 dap, mitosis resumes as a wave originating adjacent to the vascular bundle. The spindles are oriented parallel to the alveolar walls and cell plates formed in association with interzonal phragmoplasts result in periclinal walls that cut off a peripheral layer of cells and an inner layer of alveoli displaced toward the center. Polarized growth of the newly formed alveoli and elongation of the anticlinal walls occurs during interphase. The next wave of cell division in the alveoli proceeds as the first and a second cylinder of cells is cut off inside the peripheral layer. The periods of polarized growth/anticlinal wall elongation alternating with periclinal cell division are repeated 3–4 times until the grain is filled by 5 dap.     

Mitosis of the free-living flagellate Bodo saltans strain Ps+ (Kinetoplastidea, Bodonida)

Mitosis of the free-living flagellate Bodo saltans of the Ps+ strain characterized by the presence of prokaryotic cytobionts in the perinuclear space was studied. Division of B. saltans Ps+ nuclei occurs by the closed intranuclear type of mitosis without condensation of chromosomes. At the initial stages of nuclear division, consecutive anlage of two spatially separated microtubular spindles begins. The spindle containing about 20 microtubules appears first, then, at an angle of 30–40° to it, the second spindle containing half as many microtubules is formed. The microtubules of the first spindle are associated with 4 pairs of kinetochores, the microtubules of the second one—with 2 pairs. The kinetochores of B. saltans Ps+ have a pronounced laminar structure. Both spindles rest with their ends directly on the internal membrane of the nuclear envelope and form 4 well-pronounced poles. The equatorial phase of mitosis in B. saltans Ps+ is not revealed. The divergence of sister kinetochores towards the poles occurs independently in each spindle. At the elongation phase of mitosis, the poles of both spindles are united in pairs to form a single bipolar structure composed of two loose bundles of microtubules. At this stage of nuclear division, the kinetochores reach the poles of the subspindles and cease to be visible. At subsequent nuclear division stages the nucleus acquires a dumbbell shape. During the reorganization phase the sister nuclei are separated. In the perinuclear space of the interphase nuclei of B. saltans Ps+, 1–2 prokaryotic cytobionts are present. In the course of mitosis, these organisms divide intensively, such that their number can reach 20 and more per nucleus. During separation of sister nuclei, the “excessive” cytobionts are released into the cytoplasmic vacuoles formed by external membranes of the nuclear envelope.     

竹节参雌配子体发育的研究

本文报道了竹节参(Panax japonicus C.A.Mey)雌配子体(胚囊)的发育过程。竹节参大孢子母细胞减数分裂产生线形排列的大孢子四分体。胚囊发育属蓼型,由合点端大孢子发育而成。游离核胚囊时期,胚囊珠孔端的细胞器种类和数量都较胚囊合点端多;胚囊合点端相邻的珠被细胞中有含淀粉粒的小质体,与胚囊珠孔端相邻的退化中的非功能大孢子中则有含淀粉粒的大质体和大类脂体。成熟胚囊中,反足细胞较早退化;极核融合成次生核;卵细胞高度液泡化,细胞器数量较少;助细胞则有丰富的细胞器和发达的丝状器。PAS反应表明,受精前的成熟胚囊中积累淀粉粒。次生核受精后,很快分裂产生胚乳游离核,到几十至数百个核时形成胚乳细胞。卵细胞受精后则要经过较长的休眠期。     

Giant nuclei formation in the yolk sac syncytium of the muskellunge,a bony fish (salmoniformes: esocidae: Esox masquinongy)

In muskellunge blastulae the yolk sac syncytium originally contains nuclei comparable in size to the blastomere nuclei from which the syncytial nuclei arose. By mitosis the originally diploid syncytial nuclei become numerous and crowded together. Continued synchronous mitosis of neighboring syncytial nuclei and the resultant crowding together of their spindles culminates in overlapping spindles, multipolar spindles, disorganized spindles, and the crowding together of large numbers of condensed chromosomes from contigous spindles. When such an aggregation of condensed chromosomes becomes enclosed within one nuclear membrane, a giant nucleus appears in the following interphase. It soon becomes postmitotic.     

Embryo sac development in Arabidopsis thaliana

Summary Aspects of megasporogenesis in Arabidopsis thaliana have been investigated using a variety of histochemical techniques to visualize general cell organization, DNA and callose in whole ovules and sections by bright field, fluorescence, differential interference contrast and scanning electron microscopy. The microtubular cytoskeleton has been studied using immunofluorescence localization of tubulin in sections and whole cells. The observations deviate from reports of preceding studies in that the megasporocyte was found to undergo both meiotic divisions followed by simultaneous cytokinesis (i.e. without an intermediate dyad stage) to give a multiplanar tetrad of megaspores. This represents a variation of monosporic development not previously described. Polarized distribution of organelles prior to meiosis ensures that the functional megaspore receives the largest share. Aberrant wall formation is common between degenerating megaspores. Localized callose deposition in the tetrad separates these cells from the active megaspore. Their pattern of degeneration and displacement is extremely flexible within the embryo sac space. The microtubular cytoskeleton is extensive and largely cytoplasmic, as distinct from cortical, throughout megasporogenesis. In the megasporocyte, megaspores and one-nucleate embryo sac, randomly oriented microtubules throughout the cells may serve to maintain cytoplasmic integrity and position organelles. Numerous microtubules (MTs) associate closely with the nucleus and some radiate from it, perhaps functioning in nuclear positioning. During meiosis MTs are restricted to the spindle configurations and later to the phragmoplasts which form between daughter nuclei. The lack of interphase cortical arrays suggests that the role of internal influences on cell shape is small.     

Dynamics of the nuclear envelope and of nuclear pore complexes during mitosis in the Drosophila embryo

Early embryonic development in Drosophila melanogaster is marked by a series of thirteen very rapid (10-15 min) and highly synchronous nuclear divisions, the last four of which occur just beneath the embryo surface. A total of some 6000 blastoderm nuclei result, which are subsequently enclosed by furrow membranes to form the cellular blastoderm. We have examined the fine structure of nuclear division in late syncytial embryos. The mitotic spindle forms adjacent to the nuclear envelope on the side facing the embryo surface. During prophase, astral microtubules deform the nuclear envelope which then ruptures at the poles at the onset of prometaphase. The nuclear envelope remains essentially intact elsewhere throughout mitosis. A second envelope begins to form around the nuclear envelope in prometaphase and is completed by metaphase; the entire double layered structure, referred to as the spindle envelope, persists through early in the ensuing interphase. Pole cell spindles are enclosed by identical spindle envelopes. Interphase and prophase nuclei contain nuclear pore complexes (PCs) of standard dimensions and morphology. In prometaphase PCs become much less electron-dense, although they retain their former size and shape. By metaphase, no semblance of PC structure remains, and instead, both layers of the spindle envelope are interrupted by numerous irregular fenestrae. PCs are presumably disassembled into their component parts during mitosis, and reassembled subsequently. Yolk nuclei remain among the central yolk mass when most nuclei migrate to the surface, cease to divide, yet become polyploid. These nuclei nonetheless lose and regain PCs in synchrony with the dividing blastoderm nuclei. In addition, they gain and lose a second fenestrated membrane layer with the same timing. Cytoplasmic membranes containing PCs (annulate lamellae) also lose and regain pores in synchrony with the two classes of nuclear envelopes. The factors that affect the integrity of PCs in dividing blastoderm nuclei appear to affect those in other membrane systems to an equivalent degree and with identical timing.     

赤苎无融合生殖细胞胚胎学研究

对赤苎(Boehmeria silvestrii (Pamp.)W.T.Wang)细胞胚胎学研究表明,其生殖模式属无融合生殖的二倍体孢子生殖(diplospory),但其未减数胚囊的发育途径不同于已报道的类型。大孢子母细胞的减数分裂I在到达终变期时停滞,染色体呈单价体状态并维持较长的时间。在尚未到达以核膜、核仁消失,纺锤体出现为特征的中期I前,大孢子母细胞由终变期直接“跳”入间期,从而始终保持了二倍体水平。减数分裂Ⅱ正常进行并产生二倍体二分孢子。珠孔端孢子退化,合点端孢子经3次分裂形成包括1个卵细胞、2个助细胞、2个极核和3个反足细胞的八核胚囊。胚和胚乳分别起源于卵和次生核未受精的自发分裂。胚乳属核型,其发育早于胚。     

白桦雌花发育、大孢子发生及胚胎发育的解剖学观察

白桦雌花从开花到雌性器官的成熟需经历1个月左右的时间,解剖学观察表明：四月下旬越冬的雌蕊原基开始了活跃的分裂和分化。子房和柱头开始生长。四月末开花,五月初授粉。此后胚珠开始长大。五月中旬即分化形成珠被,珠心,珠被为单层珠被,胚珠为厚珠心胚珠,胚珠倒生,五月中下旬,珠心内产生大孢子母细胞,一周左右发育为成熟胚囊-七细胞八核胚囊,五月末完成双受精,白桦胚胎发育经过合子,原胚,球形胚,心形胚和鱼雷形胚等时期最后发育成熟,胚乳发育与胚胎同步,即受精的极核进行几次分裂后形成核型胚乳,胚乳核不断增多,在形成心形胚后胚乳细胞形成细胞壁。     

Origin of facultative heterochromatin in the endosperm ofGagea lutea (Liliaceae)

Summary Facultative heterochromatin occurs not only in certain animals in connection with sex determination but also in members of at least one plant genus,Gagea (Liliaceae s. str.), but here in the course of embryo sac development, fertilization, and endosperm formation. The present contribution intends to provide undebatable photographic and cytometric evidence, previously not available, for the events in the course of which three whole genomes in the pentaploid endosperm nuclei ofGagea lutea become heterochroma-tinized. In this plant, embryo sac formation usually follows the Fritillaria type, i.e., the embryo sac is tetrasporic, and a 1 + 3 position of the spore nuclei is followed by a mitosis in which the three chalazal spindles fuse and two triploid nuclei are formed. A triploid chalazal polar nucleus is derived from one of these, which contributes to the pentaploid endosperm. These nuclei in the chalazal part of the embryo sac show stronger condensation compared with the micropylar ones. The pycnosis of the triploid polar nucleus is maintained and even enhanced during endosperm proliferation, while the micropylar polar nucleus and the sperm nucleus maintain their euchromatic condition. The origin of the heterochromatic masses in the endosperm nuclei from the three chalazal genomes of the central cell is unambiguously evident from the distribution of heterochromatic chromosomes in the first endosperm mitosis and the following interphase. DNA content measurements confirm a 3 2 relationship of heterochromatic and euchromatic chromosome sets, which is usually maintained up to the cellularized endosperm. Pycnotic nuclei in the chalazal part of megagametophytes are characteristic of several embryo sac types, but only forGagea spp. it is documented that such nuclei can take part in fertilization and endosperm formation.Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

The dissociation of nuclear and centrosomal division in gnu, a mutation causing giant nuclei in Drosophila

We describe a recessive, maternal-effect lethal mutation of Drosophila, gnu. gnu uncouples nuclear division from many cytoplasmic events of mitosis in the Drosophila embryo. Embryos from homozygous females are defective in nuclear division, but not in DNA replication, and therefore develop a small number of giant nuclei. Centrosomes divide independently of nuclear division and migrate to the surface of the syncytial blastoderm. There they nucleate microtubules into asters, which appear normal at first but become very large. Only later, when the giant nuclei begin to break down, are spindles sometimes formed. The cortical actin of these embryos develops into a characteristic network.     

Unusual microtubular cytoskeleton of apomictic embryo sac of Chondrilla juncea L.

Summary. The mature apomictic embryo sac of Chondrilla juncea is highly vacuolated and demonstrates a polarization similar to that of the amphimictic gametophyte. The microtubule cytoskeleton of this embryo sac is uncharacteristic and relatively weak. The microtubules are positioned along cell walls and resemble cortical microtubules of somatic cells. They do not form the parallel, brushlike structures observed around the filiform apparatus of synergids in the amphimictic embryo sac. In the apomictic embryo sac, the microtubules of both the egg cell and the central cell develop a cortical-like structure, which is entirely different from the radial arrangement observed around the nuclei in the amphimictic embryo sac. Correspondence and reprints: Department of Plant Cytology and Embryology, Jagiellonian University, Grodzka 52, 31-044 Kraków, Poland.