Bio Notes - Protists and Bacteria PDF
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This document discusses methods of reproduction in protists, such as binary fission, multiple fission, and budding. It also covers the asexual reproduction process in bacteria via binary fission. Detailed processes and examples of these biological concepts are included in the file.
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1. Protists Protists are a diverse group of eukaryotic microorganisms that can reproduce both asexually and sexually. They are often classified based on their modes of nutrition and mobility. A. Asexual Reproduction Binary Fission: Definition: The most common method of reproduction...
1. Protists Protists are a diverse group of eukaryotic microorganisms that can reproduce both asexually and sexually. They are often classified based on their modes of nutrition and mobility. A. Asexual Reproduction Binary Fission: Definition: The most common method of reproduction in protists, where a single cell divides into two identical cells. Process: 1. DNA Replication: The protist duplicates its genetic material (DNA) so that each new cell will have a complete set of genes. 2. Cell Growth: The cell enlarges to accommodate the new DNA and prepare for division. 3. Division: The cell membrane pinches inward at the center of the cell, dividing the cytoplasm into two parts. 4. Result: Two daughter cells are formed, each genetically identical to the parent cell. Example: Amoeba undergoes binary fission by elongating and splitting in half. Multiple Fission: Definition: A method where one cell divides to produce multiple offspring simultaneously. Process: 1. The nucleus divides multiple times within the parent cell. 2. Each nucleus becomes surrounded by a small amount of cytoplasm, forming several new cells. 3. This usually occurs when conditions are unfavorable (e.g., lack of food). Example: Plasmodium, which causes malaria, undergoes multiple fission in the liver cells of its host. Budding: Definition: A small outgrowth (bud) forms on the parent organism and eventually detaches to become a new individual. Process: 1. A small bud forms on the side of the parent cell. 2. The bud grows and develops its own nucleus and organelles. 3. Eventually, it separates from the parent to live independently. Example: Yeasts like Saccharomyces cerevisiae reproduce by budding. B. Sexual Reproduction Gamete Formation: Some protists can produce gametes (reproductive cells) when conditions are harsh or stressful. Gametes are usually haploid (having one set of chromosomes), which means they contain half the genetic information needed to form a new organism. Syngamy (Fertilization): When two gametes fuse, they form a diploid zygote (a fertilized egg). This zygote has a full set of chromosomes, one from each parent. Cyst Formation: Under unfavorable conditions, some protists can form cysts, which are dormant structures that can survive extreme conditions until the environment improves. Example: In green algae like Chlamydomonas, gametes are produced when conditions are stressful, leading to fertilization and the formation of a zygote that can develop into a new organism when conditions improve. 2. Bacteria Bacteria are simple, single-celled organisms that reproduce primarily through binary fission but also have ways to exchange genetic material. A. Asexual Reproduction Binary Fission: Definition: The primary method of reproduction in bacteria. Process: 1. DNA Replication: The circular DNA chromosome replicates itself so that each daughter cell will have its own copy. 2. Cell Growth: The bacterial cell elongates as it prepares for division. 3. Septum Formation: A septum (dividing wall) begins to form in the middle of the cell. 4. Division: The septum fully divides the cell into two identical daughter cells. 5. Each daughter cell has an identical copy of the original DNA. Example: Escherichia coli can divide every 20 minutes under optimal conditions. B. Genetic Exchange Mechanisms While bacteria do not reproduce sexually, they can exchange genetic material through three main processes: Conjugation: Definition: A method where one bacterium transfers genetic material to another through direct contact. Process: 1. A donor bacterium forms a structure called a sex pilus, which connects to a recipient bacterium. 2. The donor transfers a plasmid (a small circular piece of DNA) through this pilus to the recipient bacterium. 3. The recipient bacterium can then express new traits, such as antibiotic resistance or metabolic capabilities. Example: The F plasmid in E. coli allows for genetic material transfer between bacteria. Transformation: Definition: Uptake of free DNA from the environment by a bacterial cell. Process: 1. Bacteria take up naked DNA fragments released by other bacteria that have died or lysed (broken apart). 2. This DNA can integrate into their own genome, allowing for new traits. Example: Streptococcus pneumoniae can take up DNA from its surroundings. Transduction: Definition: Transfer of bacterial DNA via bacteriophages (viruses that infect bacteria). Process:A bacteriophage infects a bacterial cell and incorporates some of its DNA into the viral genome. 3. Fungi Fungi are eukaryotic organisms that play essential roles in ecosystems as decomposers and can reproduce both sexually and asexually. A. Asexual Reproduction Spore Formation: Fungi produce spores that can be dispersed by wind or water; these spores germinate when conditions are favorable for growth. Types include:Conidia Budding and Fragmentation: Budding occurs in yeasts where a new organism grows off the parent organism until it separates completely. Fragmentation involves breaking off parts of the mycelium (the vegetative part of fungi) that develop into new individuals if they land in suitable environments. B. Sexual Reproduction Mating Types: Many fungi have different mating types (like + and −) that must come together for sexual reproduction; this ensures genetic diversity among offspring. Zygospore Formation: In some fungi (e.g., Zygomycetes), haploid hyphae from different mating types fuse to form a zygospore—a thick-walled resting spore that can survive adverse conditions—and undergo meiosis to produce spores when conditions improve. Example: In Rhizopus stolonifer (common bread mold), zygospores are formed when hyphae from different mating types meet. 4. Plants Plants have evolved complex reproductive strategies involving both sexual and asexual reproduction methods. A. Structure of Banana Plants Bananas belong to the genus Musa and have unique characteristics: 1. Root System Bananas have a fibrous root system that helps absorb water and nutrients from the soil effectively. 2. Stem (Pseudostem) The banana plant has a pseudostem made up of tightly packed leaf bases, which supports the plant and stores nutrients necessary for growth. 3. Leaves Large, broad leaves emerge from the pseudostem; they play an essential role in photosynthesis by capturing sunlight to produce energy for growth. 4. Flowering The banana plant produces an inflorescence—a flower spike—that emerges from the top of the pseudostem; this spike contains clusters known as hands, each holding several bananas. 5. Fruit Bananas develop from the ovary of flowers; they are classified as berries because they develop from a single ovary containing multiple seeds (though cultivated bananas often lack seeds). 6. Propagation Bananas reproduce through vegetative propagation using rhizomes (underground stems) or suckers (shoots emerging from the base), allowing them to spread without seeds. B. Asexual Reproduction Vegetative propagation allows new plants to grow from parts of existing plants without seeds or spores. Examples Include: 1. Stolons (Runners): Horizontal stems grow along the ground surface; e.g., strawberries produce runners that root at nodes to form new plants. 2. Tubers: Swollen underground stems store nutrients; e.g., potatoes produce eyes that sprout into new plants when conditions are right. 3. Bulbs: Underground storage organs consist of layers; e.g., onions produce new shoots from bulbs during appropriate seasons. C. Sexual Reproduction 1. Flower Structure & Development Flowers contain male structures called stamens (which produce pollen) and female structures called carpels or pistils (which contain ovules). Pollination occurs when pollen grains transfer from anther (part of stamen) to stigma (part of carpel). 2. Fertilization Process After pollination, pollen germinates on stigma, forming a pollen tube that delivers sperm cells to ovules within ovary; fertilization occurs when one sperm fertilizes an egg cell, forming a diploid zygote. 3. Seed Development The fertilized ovule develops into a seed while ovary matures into fruit; this fruit aids seed dispersal through various mechanisms such as wind, water, or animals eating fruit. 4 Example of Flower Growth Flowers develop from floral meristems through stages involving differentiation into sepals, petals, stamens, and carpels based on hormonal signals and environmental cues. Human Reproductive Systems Human reproduction involves complex physiological processes within both male and female reproductive systems. A. Male Reproductive System Parts and Functions 1. Testes Function: Produce sperm cells through spermatogenesis and secrete hormones like testosterone necessary for male development. 2. Epididymis Function: Stores sperm temporarily while they mature; sperm gain motility here over about two weeks before ejaculation. 3. Vas Deferens Function: Transports mature sperm from epididymis to ejaculatory duct during ejaculation; muscular contractions help propel sperm forward. 4. Seminal Vesicles Function: Produce seminal fluid rich in fructose that nourishes sperm and helps form semen during ejaculation; provides energy for sperm motility. 5. Prostate Gland Function: Secretes fluid that protects sperm in semen; helps neutralize acidity in female reproductive tract to enhance sperm survival. 6. Bulbourethral Glands (Cowper's Glands) Function: Produce pre-ejaculatory fluid that lubricates urethra before ejaculation occurs; helps neutralize acidity in urethra. 7. Penis Function: Delivers sperm into female reproductive tract during sexual intercourse; also serves as an exit for urine. Process of Sperm Development 1. Sperm production begins in the seminiferous tubules located within each testis where germ cells undergo several stages to become mature spermatozoa through spermatogenesis: Spermatogenesis Process Starts with spermatogonia (diploid germ cells) undergoing mitosis to produce primary spermatocytes. Primary spermatocytes undergo meiosis I resulting in two secondary spermatocytes (haploid). Each secondary spermatocyte undergoes meiosis II producing four spermatids (haploid). 2. After meiosis is complete, spermatids undergo spermiogenesis where they transform into mature spermatozoa capable of fertilization: Spermiogenesis Process Each spermatid develops a head containing genetic material and an acrosome for penetrating eggs. A tail (flagellum) forms for motility while mitochondria gather in midpiece providing energy needed for movement. 3. Maturation occurs as sperm travel from seminiferous tubules into epididymis where they gain motility over about two weeks. Process of Male Reproduction 1 During sexual arousal nerve signals stimulate blood flow leading to erection as erectile tissues fill with blood causing penis enlargement. 2 Upon ejaculation semen containing millions of sperm is expelled through urethra during sexual climax. B Female Reproductive System Parts and Functions 1. Ovaries Function: Produce eggs through oogenesis; secrete hormones like estrogen and progesterone regulating menstrual cycle. 2. Fallopian Tubes Function: Transport eggs from ovaries toward uterus; site where fertilization typically occurs if sperm is present. 3. Uterus Function: Houses developing fetus during pregnancy; has thick muscular walls capable of contracting during childbirth. 4. Endometrium Function: Inner lining of uterus where fertilized egg implants after conception; thickens during menstrual cycle preparing for potential implantation. 5. Cervix Function: Lower part of uterus connecting it to vagina; allows passage for menstrual fluid outwards and sperm inward. 6. Vagina Function: Muscular tube connecting external genitals to uterus; serves as birth canal during delivery. Ovarian Cycle The ovarian cycle consists of changes in ovarian follicles over approximately 28 days: 1 During Follicular Phase (Days 1–14): Follicles develop under follicle-stimulating hormone (FSH); one becomes dominant while others degenerate leading up to ovulation. 2 During Ovulation (Day 14): Surge in luteinizing hormone (LH) triggers release of mature egg from dominant follicle entering fallopian tube. 3 During Luteal Phase (Days15–28): Ruptured follicle transforms into corpus luteum which secretes progesterone maintaining uterine lining for potential implantation; if no fertilization occurs corpus luteum degenerates leading to menstruation. Uterine Cycle The uterine cycle corresponds with changes occurring within uterus throughout menstrual cycle: 1 Menstrual Phase: If no fertilization occurs endometrial lining sheds resulting in menstruation lasting about three to seven days. 2 Proliferative Phase: After menstruation estrogen levels rise stimulating regrowth/thickening endometrium preparing it for possible implantation after ovulation. 3 Secretory Phase: Following ovulation corpus luteum secretes progesterone further thickening endometrium while providing nutrients supporting early embryo development if fertilization occurs. Process of Female Reproduction If sperm meets an egg in fallopian tube post-ovulation fertilization occurs forming zygote which then travels down fallopian tube towards uterus implanting itself into endometrium beginning embryonic development over approximately nine months until labor occurs leading childbirth. References 1. Healthline.com – How Is Sperm Produced? Healthline 2. National Center for Biotechnology Information – Endocrinology of Male Reproductive System NCBI 3. MedlinePlus – Anatomy Videos MedlinePlus 4. Nemours KidsHealth – Male Reproductive System KidsHealth 5. MSD Manuals – Structure of Male Reproductive System MSD Manuals 6. WebMD – The Male Reproductive System WebMD