Biology 311C Extra Credit

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Inheritance

Ved laura cook

Cell Transport

Ved Sunny Yang

Mind Maps Biology 2021 Grade 11

Ved Victor Yu

Project 4 Solar energy

Ved Mariam Kolaghassi

Eukaryote Translation vs. Prokaryote Translation 1. Ribosomes. Eukaryotic ribosomes are larger. They consist of a 60S large subunit and a 40S small subunit, which come together to form an 80S, compared with the prokaryotic 70S ribosome. 2. Initiator tRNA. In eukaryotes, the initiating amino acid is methionine rather than N-formylmethionine. However, as in prokaryotes, a special tRNA participates in initiation. This aminoacyl-tRNA is called Met-tRNAi or Met-tRNAf. 3. Initiation. The initiating codon in eukaryotes is always AUG. Eukaryotes. The AUG nearest the 5′ end of mRNA is usually selected as the start site. A 40S ribosome attaches to the cap at the 5′ end of eukaryotic mRNA and searches for an AUG codon by moving step-by-step in the 3′ direction. This scanning process in eukaryotic protein synthesis is powered by helicases that hydrolyze ATP. Pairing of the anticodon of Met-tRNAi with the AUG codon of mRNA signals that the target has been found. In almost all cases, eukaryotic mRNA has only one start site. A prokaryotic mRNA can have multiple Shine-Dalgarno sequences and start sites, and it can serve as a template for the synthesis of several proteins. Eukaryotes utilize many more initiation factors than do prokaryotes. The difference in initiation mechanism between prokaryotes and eukaryotes is a consequence of the difference in RNA processing. The 5′ end of mRNA is readily available to ribosomes immediately after transcription in prokaryotes. In contrast, pre-mRNA must be processed and transported to the cytoplasm in eukaryotes before translation is initiated. There are secondary structures that must be removed to expose signals in the mature mRNA. The 5′ cap provides an easily recognizable starting point.

Just because an organisim posses a certain gene(genotype) doesn't mean it will be the gene visibly expressed(phenotype). For example, take Joey. Joey's genotype may include the dominant gene for black hair, Bb, and the recessive gene for brown hair,rr. His genotype includes both the dominant and recessive genes, however, as far as his phenotype is concerened, he just has black hair. This is similar to how cells know what kind of cell to be. This applies, most notably, to plants and animals.

Biology 311C Extra Credit

Big Idea 1

Recognize living organisms, and be able to classify them into domains and kingdoms reflecting their evolutionary history.

Eubacteria

Protists

Animals

This concept map starts off by focusing on the big picture, and then progressivly narrowing it down to cells, the basic units of life. I started off by detailing the Domains, and from the domains to the kingdoms. Then I switched gears and showed how the cells that make up these kingdoms get their energey, and finally I finish with what makes each organism unique. In Big Idea 1, I touched on the differences between the three domains and the different kingdoms of organisms. Big Idea 2 focuses on the processes that power the cells that make up the organisms. Finally, Big Idea 3 compares the different processes and genetic make up of these organisms

The Animalia Kingdom is further divided into mammals, fish, birds, insects, and etc.

Fungi

Plants

Despite Fungi being its own Kingdom, it is often included in the Plant Kingdom.

Compare cellular structures and their corresponding functions in the three domains of life.

Bacteria

Bacteria are the most widespread and diverse prokaryotes and are now classified into multiple kingdoms. Each rod-shaped structure showed in the picture is a bacteria cell.

Cellulaqr Structure: DNA Cytoplasm Cell Wall Ribosomes

Eukaryotes

The Eukaryotes span a wide variety of kingdoms and all of them have different characteristics, features, and habitats. Featured in the picture are Protists, Animals, Plants Fungi.

Cellular Structure: All eukaryotic cells have nucleus DNA plasma membrane Ribosomes Cytoplasm/cytoskeleton Most eukaryotic cells also have other membrane-bound internal structures called organelles. Mitochondria Golgi bodies Lysosomes Endoplasmic reticulum Vesicles There are a few major differences between animal, plant, fungal, and protistan cells, and guess what? Here they are: All plant cells have cell wall made of cellulose central vacuole Chloroplasts Some animal and protistan cells have Flagella Cilia All animal cells have Centrioles All fungal cells have cell wall made of chitin.

Archaea

Archaea are single celled, and lack organelles. They can live in a braod range of habitats. Each cell above is one Archaea cell.

Cellular Structure: DNA-Genetic Information Cell Membrane-Inner fluid Cell Wall-Outter Protective Membrane

Big Idea 2

State an overview of cellular respiration in terms of the overall redox changes and energy-­‐coupled reactions that occur.

Compare and contrast mitochondria and chloroplasts in terms of how they are uniquely structured to make ATP during oxidative or photo-­‐phosphorylation respectively.

Mitochrondria(Animal Cells)

While the intial part of glycolysis occurs outside of the mitochondria, it is still important in the production of ATP. The Krebs cycle occurs in the Matrix of the mitochondria. The Electron Transport Chain occurs in an inner part of the mitochondria called the Crista.

Chloroplasts(plant cells)

The chlorophyll absorbs the sunlight that is used. The Electron Transport Chains, photosynthetic light-capturing systems, and ATP synthase are all contained in the thylakoid membrane. The Calvin cycle occurs in the stroma of chloroplasts.

Big Idea 3

Distinguish between genotype and phenotype, and give examples that relate this distinction to the dominant and recessive effects of certain alleles and to the molecular mechanisms of gene action.

Phenotype

Phenotype are the visible genes that are expressed

Genotype

Genotype is the assortment of genes an organism posseses.

Compare the processes of transcription and translation between prokaryotic and eukaryotic cells in terms of location, time and cell components.

Eukaryotic Cells

Transcription and translation are spatially and temporally separated in eukaryotic cells; that is, transcription occurs in the nucleus to produce a pre-mRNA molecule. The pre-mRNA is typically processed to produce the mature mRNA, which exits the nucleus and is translated in the cytoplasm. Introns must be cut out before the mRNA can be functional. This occurs in the cytoplasm.

Prokaryotic Cells

Translation

Transcription

Because there is no nucleus to separate the processes of transcription and translation, when bacterial genes are transcribed, their transcripts can immediately be translated. Unlike Eukaryotic cells, Prokaryotic cells don't need to go through the pre-mRNA phase. Transcription and Translation are coupled here.