981 resultados para Escola Superior de Agricultura Luiz de Queiroz
Resumo:
The authors studied the action of arsenic, in the form of lead arsenate and sodium arsenite, on cotton in white sandy soil of Piracicaba, State of S. Paulo, Brazil. The experiment was carried out in Mitscherlich pots, applying increasing quantities of the above mentioned compounds. The following conclusions were reached: sodium arsenite is more toxic than lead arsenate. 48 pounds per acre of lead arsenate and 16 pounds per acre of sodium arsenite reduced the vegetative development and the production of cotton. The roots were more seriously affected than the aerial parts. Sandy soils were sensitive to arsenic toxicity. The arsenic mobilization in the soil seems to depend upon factors such as, the a- cidity, the concentration of Fe2O3, CaO, P2O5 and soil colloids, both clay and humus components. The authors suggest, based on their own experiment and after a detailed study of the literature, the use of organic insecticids which may not leave toxic residues, rotation of crops, application of lime and reduction of arsenical sprays to a mini mum. Arsenic compounds should not be used in soils destined to the cultivation of food plants. Rice should not be planted in soils contaminated by arsenic compounds during several years of cotton cultivation. Future experiments are planed, using other soils such as "terra roxa", in Mitscherlich pots and in field plots.
Resumo:
A morfologia, ocorrência, utilidade e genética das flores funcionais inferiores em espiguetas de milho, são examinadas ligeiramente. Em regra, somente a flor superior em cada espigueta numa espiga de milho se desenvolve e contém um grão, porém nos exemplos em foco a flor inferior se desenvolve tão bem como a superior. O embrião no milho geralmente se acha voltado na mesma direção que a ponta da espiga, ao passo que o embrião do grão proveniente da flor inferior se volta na direção da base. São raras, não só na América do Norte e Central, como na maior parte da América do Sul, as espigas nas quais os grãos provêm da flor inferior das espiguetas, constituindo uma exceção o milho doce Country Gentleman, no qual se encontram grãos em ambas as flores na maioria das espiguetas. No Brasil e na Bolívia, entretanto, são mais comuns as espigas com espiguetas de dois grãos. Sendo o milho proveniente da América do Sul, é de esperar-se que se encontrem mais variedades e tipos mais primitivos próximo do centro de origem. No milho Pipoca Pontudo Paulista, o Dr. BRIEGER encontrou espigas com ambas as flores funcionais em algumas espiguetas. Em alguns casos, ambos os grãos eram de tamanho normal, porém, mais comumente, um dos dois grãos era bem menor que o outro. Em espigas encontradas pelo Dr. MARTIN CARDENAS, algumas espiguetas apresentam grãos provindos somente das flores inferiores, uma circunstância característica do grupo "Poaceae", e não do "Panicaceae" a que pertence o milho. Muitos gens que influenciam os característicos do pendão, também influenciam os das espigas. Alguns destes controlam a formação de grãos na flor inferior da espigueta-fêmea. A maioria dos gens conhecidos como afetando as espiguetas inferiores, são recessivos, tal como no caso das espigas brasileira e boliviana estudadas, e no Country Gentleman. Um exemplo de espiguetas gêmeas foi encontrado entre o material tunicata do Dr. BRIEGER. Aí, em vez de uma só espi-gueta, o que é o normal, havia duas espiguetas completas, simétricas, sendo uma em posição oposta ao normal. Os grãos, em ambas, achavam-se na flor superior. Prosseguem os estudos sobre a espigueta do milho. O Dr. GONÇALVES DRUMOND, da Escola Superior de Viçosa, Minas Gerais, encontrou recentemente algumas espigas de "Cateto", nas quais a flor inferior é funcional e está estudando as mesmas. Parece que o mais interessante material para os novos estudos é o que o Dr. BRIEGER encontrou no seu milho "Pipoca Pontudo Paulista, pois há ai graus variáveis de desenvolvimento tanto superiores como inferiores.
Resumo:
Na Seção de Avicultura da Escola Superior de Agricultura "Luiz de Queiroz", da Universidade de São Paulo, foi iniciada uma experiência de pastagens para galinhas, para determinação das espécies mais adequadas ao fim visado. Os resultados obtidos neste primeiro ano de experiência indicaram a seguinte classificação: 1.o - Consociação de Grama Seda (Cynodon dactylon Pers.) var.? com Capim Quicúio (Pennisetum clandestinum Chiov.). 2.0 - Grama Seda (Cynodon dactylon Pers.) var.? 3.0 - Capim Quicúio (Pennisetum clandestinum Chiov.). 4.O - Grama de Batatais (Palpalum notatum Flügge.). 5.o - Uma grama ainda não determinada. 6.o - Grama Paulista (Cynodon dactylon Pers.) var.? A variedade Gigante de Cynodon dactylon Pers. não deu resultados satisfatórios. A experiência será continuada.
Resumo:
In this paper an account is given of the principal facts observer in the meiosis of Euryophthalmus rufipennis Laporte which afford some evidence in favour of the view held by the present writer in earlier publications regarding the existence of two terminal kinetochores in Hem ip ter an chromosomes as well as the transverse division of the chromosomes. Spermatogonial mitosis - From the beginning of prophase until metaphase nothing worthy of special reference was observed. At anaphase, on the contrary, the behavior of the chromosomes deserves our best attention. Indeed, the chromoso- mes, as soon as they begin to move, they show both ends pronouncedly turned toward the poles to which they are connected by chromosomal fibres. So a premature and remarkable bending of the chromosomes not yet found in any other species of Hemiptera and even of Homoptera points strongly to terminally localized kinetochores. The explanation proposed by HUGHES-SCHRADER and RIS for Nautococcus and by RIS for Tamalia, whose chromosomes first become bent late in anaphase do not apply to chromosomes which initiate anaphase movement already turned toward the corresponding pole. In the other hand, the variety of positions assumed by the anaphase chromosomes of Euryophthalmus with regard to one another speaks conclusively against the idea of diffuse spindle attachments. First meiotic division - Corresponding to the beginning of the story of the primary spermatocytes cells are found with the nucleus entirelly filled with leptonema threads. Nuclei with thin and thick threads have been considered as being in the zygotente phase. At the pachytene stage the bivalents are formed by two parallel strands clearly separated by a narrow space. The preceding phases differ in nothing from the corresponding orthodox ones, pairing being undoubtedly of the parasynaptic type. Formation of tetrads - When the nuclei coming from the diffuse stage can be again understood the chromosomes reappear as thick threads formed by two filaments intimately united except for a short median segment. Becoming progressively shorter and thicker the bivalents sometimes unite their extremities forming ring-shaped figures. Generally, however, this does not happen and the bivalents give origin to more or less condensed characteristic Hemipteran tetrads, bent at the weak median region. The lateral duplicity of the tetrads is evident. At metaphase the tetrads are still bent and are connected with both poles by their ends. The ring-shaped diakinesis tetrads open themselves out before metaphase, showing in this way that were not chiasmata that held their ends together. Anaphase proceeds as expected. If we consider the median region of the tetrads as being terminalized chiasmata, then the chromosomes are provided with a single terminal kinetochore. But this it not the case. A critical analysis of the story of the bivalents before and after the diffuse stage points to the conclusion that they are continuous throughout their whole length. Thence the chromosomes are considered as having a kinetochore at each end. Orientation - There are some evidences that Hemipteran chromosomes are connected by chiasmata. If this is true, the orientation of the tetrads may be understood in the following manner: Chiasmata being hindered to scape by the terminal kinetochores accumulate at the ends of the tetrads, where condensation begins. Repulsion at the centric ends being prevented by chiasmata the tetrads orient themselves as if they were provided with a single kinetochore at each extremity, taking a position parallelly to the spindle axis. Anaphase separation - Anaphase separation is consequently due to a transverse division of the chromosomes. Telophase and secund meiotic division - At telophase the kinetochore repeli one another following the moving apart of the centosomes, the chiasmata slip toward the acentric extremities and the chromosomes rotate in order to arrange themselves parallelly to the axis of the new spindle. Separation is therefore throughout the pairing plane. Origin of the dicentricity of the chromosomes - Dicentricity of the chromosomes is ascribed to the division of the kinetochore of the chromosomes reaching the poles followed by separation and distension of the chromatids which remain fused at the acentric ends giving thus origin to terminally dicentric iso-chromosomes. Thence, the transverse division of the chromosomes, that is, a division through a plane perpendicular to the plane of pairing, actually corresponds to a longitudinal division realized in the preceding generation. Inactive and active kinetochores - Chromosomes carrying inactive kinetochore is not capable of orientation and active anaphasic movements. The heterochromosome of Diactor bilineatus in the division of the secondary spermatocytes is justly in this case, standing without fibrilar connection with the poles anywhere in the cell, while the autosomes are moving regularly. The heterochromosome of Euryophthalmus, on the contrary, having its kinetochores perfectly active ,is correctly oriented in the plane of the equator together with the autosomes and shows terminal chromosomal connection with both poles. Being attracted with equal strength by two opposite poles it cannot decide to the one way or the other remaining motionless in the equator until some secondary causes (as for instances a slight functional difference between the kinetochores) intervene to break the state of equilibrium. When Yiothing interferes to aide the heterochromosome in choosing its way it distends itself between the autosomal plates forming a fusiform bridge which sometimes finishes by being broken. Ordinarily, however, the bulky part of the heterochromosome passes to one pole. Spindle fibers and kinetic activity of chromosomal fragments - The kinetochore is considered as the unique part of the chromosome capable of being influenced by other kinetochore or by the poles. Under such influence the kinetochore would be stimulated or activited and would elaborate a sort of impulse which would run toward the ends. In this respect the chromosome may be compared to a neüròn, the cell being represented by the kinetochore and the axon by the body of the chromosome. Due to the action of the kinetochore the entire chromosome becomes also activated for performing its kinetic function. Nothing is known at present about the nature of this activation. We can however assume that some active chemical substance like those produced by the neuron and transferred to the effector passes from the kinetochore to the body of the chromosome runing down to the ends. And, like an axon which continues to transmit an impulse after the stimulating agent has suspended its action, so may the chromosome show some residual kinetic activity even after having lost its kinetochore. This is another explanation for the kinetic behavior of acentric chromosomal fragmehs. In the orthodox monocentric chromosomes the kinetic activity is greater at the kinetochore, that is, at the place of origin of the active substance than at any other place. In chromosomes provided with a kinetochore at each end the entire body may become active enough to produce chromosomal fibers. This is probably due to a more or less uniform distribution and concentration of the active substance coming simultaneously from both extremities of the chromosome.
Resumo:
Spermatogonial chromosomes of Pachylis laticornis and Pachylis pharaonis begin anaphasic movement with both ends turned toward the same pole, maintaining this form util they reach the poles. This is a proof that they are provided with one kinetochore at each end. Additional proof for a longitudinal division of each longitudinal half of the anaphase chromosomes of the primary sper- matocytes is presented against the idea of a previous end-toend pairing at metaphase. The longitudinal split of the chromosomes of the secondary spermatocytes which used to be considered as tertiary split is therefore a true secondary split. The heterochromosome in both species passes undivided to one pole in the first division of the spermatocyte. In Pachylis laticornis it appears connected with the poles by means of two fibrils detached from each extremity, what may be considered as indicating a rather premature longitudinal spliting. The behavior of the heterochromosome of Pachylis pharaonis is highly interesting and affords one of the most beautiful evidences in favour of the dicentricity of the chromosomes. Really, in metaphase the heterochromosome appears at the equator of the cell with a more or less round shape. In the beginning of anaphase it becomes fusiform. As anaphase proceeds it distends itself between the autosomal plates forming a long fusiform bridge or sends toward the plates a thick chromosomal thread. The bulky part of the heterochromosome as it passes to one side it reincorporates the substance of the thread in this side. The thread in the other side, which becomes generally thiner, is left with its kinetochore in the cell at this side. The heterochromosome therefore becomes terminally monocentric in the first division of the spermatocyte. Some figures, however, suggest that the heterochromossome from time to time may pass with both kinetochores to one of the cells, as ordinarily happens in the case of Pachylis laticornis. Summing up, other things apart the behavior of the heterochromosome in both species studied here puts out of doubt the question of the existence of two terminally located kinetochores.
Resumo:
The male of Eneoptera surinamensis (Orthoptera-Eneopteridae) is provided with 9 chromosomes, that is, with 3 pairs of autosomes and 3 sex chromosomes. Spermatogonia. - The autosomes of the spermatogonia are of the same size and U-shaped. One of the sex chromosomes approximately equalling the autosomes in size is telocentric, while the other two are much larger and V-shaped. One of the latter is smaller than the other. The sex chromosomes as showed in Figs. 1 and 2 are designated by X, Yl and Y2, X being the larger V, Yl the smaller one and Y2 the rod-shaped. Primary spermatocytes. - Before the growth period of the spermatocytes all the three sex chromosomes are visible in a state of strong heteropycnosis. X is remarkable in this stage in having two long arms well separated by a wide commissural segment. (Figs. 4, 5 and 6). During the growth period Y2 disappears, while X and Yl remain in a condensed form until metaphase. These may be separated from one another or united in the most varied and irregular manner. (Fig. 7 to 12). In the latter case the segments in contact seem to be always different so that we cannot recognize any homology of parts in the sense os genetics. At diplotene Y2 reappears together with the autosomal tetrads. X and Yl may again be seen as separate or united elements. (Figs. 13 and 14). At later diakinesis and metaphase the three sex chromosomes are always independent from each other, Y2 being typically rod-shaped, X and Yl V-shaped, X being a little larger than Yl. (Fig. 15 to 18). At metaphase the three condensed tetrads go to the equatorial plane, while the sex chromosomes occupy any position at both sides of this plane. In almost all figures which could be perfectly analysed X appeared at one side of the autosomal plate an Yl together with Y2 far apart at the other side. (Figs. 16 and 18). Only a few exception have been found. (Figs. 17 and 19). At anaphase X goes in precession to one pole, Yl and Y2 to the other (Figs. 20 and 21). As it is suggested by the few figures in which a localization of the sex chromosomes different from the normal has been observed, the possibility of other types of segregation of these elements cannot be entirely precluded. But, if this does happen, the resulting gametes should be inviable or give inviable zygotes. Early in anaphase autosomes and sex chromosomes divide longitudinally, being maintained united only by the kinetochore. (Figs. 20 and 21). At metaphase the three sex chromosomes seem to show no special repulsion against each other, X being found in the proximity of Yl or Y2 indifferently. At anaphase, however, the evidences in hand point to a stronger repulsion between X on the one side and both Ys on the other, so that in spite of the mutual repulsion of the latter they finish by going to the same pole. Secondary spermatocytes. - At telophase of the primary spermatocytes all the chromosomes enter into distension without disappearing of view. A nuclear membrane is formed around the chromosomes. All the chromosomes excepting Y2 which has two arms, are four-branched. (Fig. 22). Soon the chromosomes enter again into contraction giving rise to the secondary metaphase plate. Secondary spermatocytes provided as expected with four and five chromosomes are abundantly found. (Figs. 23 and 24). In the former all chromosomes are X-shaped while in the latter there is one which is V-shaped. This is the rod- shaped Y2. In the anaphase of the spermatocytes with four chromosomes all the chromosomes are V-shaped, one of them (X) being much larger than the others. In those with five there is one rod-shaped chromosome (Y2). (Fig. 25), Spermatids. Two classes of spermatids are produced, one with X and other with Yl and Y2. All the autosomes as well as Y2 soon enter into solution, X remaining visible for long time in one class and Yl in the other. (Figs. 26 and 27). Since both are very alike at this stage, one cannot distinguish the two classes of spermatids. Somatic chromosomes in the famale. - In the follicular cells of the ovary 8 chromosomes were found, two of which are much larger than the rest. (Figs. 29 and 30). These are considered as being sex chromosomes. CONCLUSION: Eneoptera surinamensis has a new type of sex-determining mechanism, the male being X Yl Y2 and the female XX. The sex chromosomes segregate without entering into contact at metaphase or forming group. After a review of the other known cases of complex sex chromosome mechanism the author held that Eneoptera is the unique representative of a true determinate segregation of sex chromosomes. Y2 behaving as sex chromosome and as autosome is considered as representing an intermediary state of the evolution of the sex chromosomes.
Resumo:
In order to test Piza's conclusions regarding the dicentricity of Hemipteran chromosomes, two species of bugs of the family Coreidae, namely, Anasa sp. and Leptoglossus stigma (Herbst), are studied in the present paper. a) Anasa sp. - The male of this species has 21 chromosomes, that is, 20 pairs of autosomes and a single sex chromosome. The latter divides equationally in the first division of the spermatocytes and passes undivided to one cell in the second division. In this it moves with its longer axis parallelly to the spindle axis and shows fibrillar connections with both poles. Special attention was paid to the behavior of the chromosomes in the anaphase of the spermatogonia. As it was previously stated (Piza 1946 and 1946a) with regard to other species, the chromosomes are here attached to the spindle by both ends and begin to move toward the poles strongly curved to them. No intercalary fibers could be detected although their existente may not be denied by theoretical reasons developed in another paper (Piza 1946). Mitoses in somatic tissues of the embryo were equally studied. Careful examination of anaphase chromosomes in a great number of cells showed that the chromosomes behave exactly as in the spermatogonia, being equally attached to the spindle by the extremities alone and moving with their ends looking to the pole. A weak median constriction sometimes replaced by a slightly clearer space was observed in prometaphase and even in metaphase chromosomes of the spermatogonia as well as the somatic cells, having already been referred to in the case of Diactor bilineatus. (Piza 1945). Hemipteran chromosomes being considered as iso-chromosomes originated by a longitudinal spliting of the monocentric chromosomes resulting from the second division of the spermatocytes, the median aspect just mentioned may be regarded as the point of union of the separated halves. (See origin of dicentricity in Piza 1946). b) Leptoglossus stigma - This species has spermatogonia provided with 20 pairs of autosomes and one sex chromosome whose behavior differs in nothing from what was stated in regard of the preceding species. In the primary spermatocytes nothing meriting special mention was observed. Orientation, connection with the poles and movements of the sex chromosome in the secondary spermatocytes confirm the views already developed.
Resumo:
1) Um estudo sobre o modo de crescimento de alones tetraplóides de mandioca Vassourinha Paulista, obtido experimentalmente por meio da colquicina, foi feito em comparação ao crescimento de clones diplóides da mesma variedade. Três outros clones da mandiosa amargosa foram também incluidos na análise para comparação. As observações foram feitas nas hastes da primeira ramificação de cada planta e podem ser resumidas como segue: (Quadros n.°s 1 e 2). a) comprimento: Dos 6 clones tetraplóides analisados, 5 (n.°s 1, 3, 6, 5 e 7) tiveram um comprimento bem menor que o dos clones controles diplóides, mostrando assim serem plantas menores. Um único clone tetraplóide (n.° 15) teve um comprimento menor, porém com a média não estatisticamente diferente da média do clone diplóide. b) peso: Os seis clones tetraplóides formaram dois grupos, com relação ao peso das hastes: um grupo de 3 clones (n.°s 1, 3 e 6) com o peso médio diferente do peso médio dos controles e um grupo de 3 clones (n.°s 5, 7 e 15) com peso médio não diferindo dos controles. Estes resultados estão confirmados pelo valor do índice pêso/n.° de folhas. c) n.° de folhas: O número de folhas por unidade de comprimento foi praticamente o mesmo para os clones diplóides e tetraplóides, conforme se pode verificar pelos valores do índice comprimento/n.° de folhas. Pode-se concluir que os clones tetraplóides têm um hábito de crescimento diferente daquele dos clones diplóides; as plantas tetraplóides são menores que as diplóides e, entre os clones tetraplóides, houve também diferença, alguns clones tendo plantas mais finas que outros. As estacas da variedade Vassourinha Paulista, de onde partimos para a obtenção das formas poliplóides, não foram obtidas de uma única planta e assim não podemos garantir se a diferença verificada entre os clones tetraplóides seja devida a clones iniciais diferentes ou se produzida ainda pela colquicina. 2) A produção de raizes e ramas numa experiência de um ciclo vegetativo, em blocos ao acaso e cem 3 repetições, foi analisada e mostrou que a produção dos clones diplóides é maior que aquela dos clones tetraplóides (Quadro n.° 10). A produção dos clones tetraplóides não foi uniforme. Eles formaram uma seqüência de produção e pelo menos um clone, o de n.° 6, ficou significativamente fora do conjunto, quando a sua média foi comparada à média de raiz e rama obtidas do total de clones tetraplóides. Este clone foi o único tetraplóide do grupo de 3 com estacas mais finas, indicados na análise de crescimento, que entrou na experiência; êle confirma assim aquela separação. O índice rama/raiz foi menor para os clones diplóides que para os tetraplóides, indicando que a produção de raiz em relação à rama é menor nos clones tetraplóides, no primeiro ciclo, provavelmente devido ao retardamento de crescimento nos primeiros meses de vegetação, pois as plantas tetraplóides cresceram mais vagarosamente que as plantas diplóides. 3) Uma experiência com 2 ciclos vegetativos e 3 repetições, mostrou que o clone tetraplóide n.° 6 (Quadro n.° 20) é de fato diferente dos demais, tendo plantas muito pequenas e produção muito pequena no campo. Esta experiência mostrou também que o clone n.° 2, que foi o tetraplóide mais produtivo na experiência com um ciclo vegetativo, parece formar um outro grupo tetraplóide com relação a produção de raizes e ramas. Esta experiência de dois ciclos foi realizada com um espaçamento bastante grande, de modo a eliminar toda possível competição entre plantas; os valores médios de produção por planta, contidos no quadro n.° 20, servem para identificar um clone do outro mas não representam produção comercial. Com 2 ciclos vegetativos o índice rama/raiz torna-se igual para todos os clones, mostrando que, após o primeiro ciclo, a produção de raiz em relação à rama torna-se idêntica para todos os clones. A correlação positiva entre produção de rama e raiz é significante e grande, tanto com um como com 2 ciclos vegetativos. 4) Mais uma experiência com um ciclo vegetativo, feita sistematicamente e com os clones n.° 8 (controle) e clones tetraplóides n.°s 2 e 6, confirmou os resultados anteriores, isto é, que a produção por planta dos clones tetraplóides é menor que a produção dos clones diplóides e que existe diferença entre os clones tetraplóides obtidos (quadro n.° 26). O aproveitamento comercial dos melhores clones tetraplóides só poderá ser avaliado depois da realização de experiências de espaçamento, pois é possível que, com um maior número de plantas, possa se obter a mesma ou melhor produção que os clones diplóides, numa mesma área. O clone tetraplóide n.° 6 não suporta as condições de campo (Fig. 32) e é possível que, pelo pequeno tamanho de suas plantas, seja útil para condições hortícolas, uma questão já discutida em outra publicação (6). 5) Uma análise de estacas para plantação, medindo 20 cms. cada uma, mostrou que há diferença de peso entre estacas dos clones tetraplóides. O clone n.° 6 teve um valor médio menor e diferindo estatisticamente dos demais clones tetraplóides, confirmando assim outros resultados anteriores. 6) Um estudo detalhado sobre a percentagem de amido dos diferentes clones mostrou que os tetraplóides não diferem dos diplóides quanto ao teor amido e que eles não são também diferentes de 3 outros clones de mandioca amargosa incluidos na análise para comparação.
Resumo:
The main facts presented in this paper may be summarized as follows: 1) Corizus (Liorhyssus) hyalinus (Fabr.) has primary spermatocytes provided with 6 autosomal tetrads, one pair of microchromosomes and one sex chromosome. 2) The two microchromosomes present in this species sometimes appear at the primary metaphase as an unequal pair of minute elements. In the secondary spermatocytes the unique microchromosome present may be in the limit of visibility or entirely invisible. This invisibility may be partly due to a loss of colourability. 3) The sex chromosome divides transversely in the first division of the spermatocyte, passing undivided to one pole in the second one. In the latter it becomes fusiform in the beginning of anaphase revealing in this manner its dicentricity. In late anaphase it finishes by passing to one pole leaving in the other pole one of its kinetochores sometimes accompanied by a chromosomal fragment. 4) All the chromosomes divide transversely in both divisions, a diagram being enclosed to elucidate the question. 5) Spermatogonial chromosomes are provided with one kinetochore at each end, being curved toward the poles since the most beginning anaphase. 6) The following hypothesis is presented as an essay to explain the origin of microchromosomes: Since microchromosomes parallel sex chromosomes in most respects, as for instances in heteropycnosis and pairing modus, it seems highly probable that they originate from sex chromosomes. One may suppose that the ancestral form of a given species had a sex chromosome which used to lose a small centric fragment when it divided during meiosis. This fragment might well be at first an unstable one. Later, to compensate the effects of such a deficiency a mechanism arose through evolution which produced two useful results : a) the establishment of the fragment as a permanent structure of the cell nucleus and b) the acquirement by the sex chromosome of the faculty of passing to one pole without losing any of its ends.
