Questões de Concurso Público Prefeitura de Iporã do Oeste - SC 2020 para Professor de Inglês
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Alguns recursos que podem ser utilizados como apoio nas aulas de produção escrita em Língua Inglesa são:
I. Dicionário, mono ou bilíngue.
II. Glossário construído em sala de aula.
III. Guias de apoio, que contenham conjugações, elementos gramaticais e características dos tipos de textos em estudo.
Está correto o que se afirma em:
Leia o texto abaixo.
“A aprendizagem é, então, percebida como ocorrendo no que se denomina de Zona de Desenvolvimento Proximal. Esse espaço é caracterizado pelas interações entre aprendizes e parceiros mais competentes, explorando o nível real em que o aluno está e o seu nível em potencial para aprender sob a orientação de um parceiro mais competente. Note-se que essa concepção da aprendizagem tem sido usada para explicar a aprendizagem dentro e fora da escola.”
(Fonte: Brasil. Secretaria de Educação Fundamental. Parâmetros curriculares nacionais: terceiro e quarto ciclos do ensino fundamental: língua estrangeira / Secretaria de Educação Fundamental. pág. 58. Brasília :MEC/SEF, 1998.)
O texto menciona a zona de desenvolvimento proximal, conceito elaborado por:
Read the text below to answer the question.
How octopuses ‘taste’ things by touching
Octopus arms have minds of their own. Each of these eight supple yet powerful limbs can explore the seafloor in search of prey, snatching crabs from hiding spots without direction from the octopus’ brain. But how each arm can tell what it’s grasping has remained a mystery.
Now, researchers have identified specialized cells not seen in other animals that allow octopuses to “taste” with their arms. Embedded in the suckers, these cells enable the arms to do double duty of touch and taste by detecting chemicals produced by many aquatic creatures. This may help an arm quickly distinguish food from rocks or poisonous prey, Harvard University molecular biologist Nicholas Bellono and his colleagues report online October 29 in Cell.
The findings provide another clue about the unique evolutionary path octopuses have taken toward intelligence. Instead of being concentrated in the brain, two-thirds of the nerve cells in an octopus are distributed among the arms, allowing the flexible appendages to operate semiindependently.
(Adapted from: https://www.sciencenews.org/article/octopus-taste-touch-arm-suckers).
Read the text below to answer the question.
How octopuses ‘taste’ things by touching
Octopus arms have minds of their own. Each of these eight supple yet powerful limbs can explore the seafloor in search of prey, snatching crabs from hiding spots without direction from the octopus’ brain. But how each arm can tell what it’s grasping has remained a mystery.
Now, researchers have identified specialized cells not seen in other animals that allow octopuses to “taste” with their arms. Embedded in the suckers, these cells enable the arms to do double duty of touch and taste by detecting chemicals produced by many aquatic creatures. This may help an arm quickly distinguish food from rocks or poisonous prey, Harvard University molecular biologist Nicholas Bellono and his colleagues report online October 29 in Cell.
The findings provide another clue about the unique evolutionary path octopuses have taken toward intelligence. Instead of being concentrated in the brain, two-thirds of the nerve cells in an octopus are distributed among the arms, allowing the flexible appendages to operate semiindependently.
(Adapted from: https://www.sciencenews.org/article/octopus-taste-touch-arm-suckers).
Read the text below to answer the question.
How octopuses ‘taste’ things by touching
Octopus arms have minds of their own. Each of these eight supple yet powerful limbs can explore the seafloor in search of prey, snatching crabs from hiding spots without direction from the octopus’ brain. But how each arm can tell what it’s grasping has remained a mystery.
Now, researchers have identified specialized cells not seen in other animals that allow octopuses to “taste” with their arms. Embedded in the suckers, these cells enable the arms to do double duty of touch and taste by detecting chemicals produced by many aquatic creatures. This may help an arm quickly distinguish food from rocks or poisonous prey, Harvard University molecular biologist Nicholas Bellono and his colleagues report online October 29 in Cell.
The findings provide another clue about the unique evolutionary path octopuses have taken toward intelligence. Instead of being concentrated in the brain, two-thirds of the nerve cells in an octopus are distributed among the arms, allowing the flexible appendages to operate semiindependently.
(Adapted from: https://www.sciencenews.org/article/octopus-taste-touch-arm-suckers).
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