Cell Biology I

Universitat Internacional de Catalunya

Credits: 6

Code: 13467

Course: 1

Term: First semester

Type: FB

Module:

Matter: BIOLOGY

Main language of instruction: Spanish

Other languages of instruction: Catalan, English

Teaching staff

Head instructor:
Dr. BOSCH PITA, Miguel - miquelbosch@uic.es

Office hours:

Students can ask any question regarding the course and the content, or set an appointment with the coordinator or directly with any of the teachers, via the email.

Teaching staff:

Course coordinator, magisterial classes, case methods: Miquel Bosch: miquelbosch@uic.es
Magisterial classes and case methods on development: Andrea Santuy Muñoz: asantuy@uic.es
Laboratory teacher: Sara Plutta: skplutta@uic.es

Introduction

The cell is the basic functional unit of all living beings. Cell biology is responsible for the study of cells and their properties: their structure, their functions, their composition, heir life cycle, and their interaction with the environment and with other cells in the development of multicellular tissues. This course is complemented with the knowledge from the areas of Molecular Biology, Biochemistry, Histology and Physiology.

Pre-course requirements

Previous scientific training (highschool level), including:

Knowledge of the bases of biochemistry (types of biological molecules, -DNA, RNA, proteis, etc.-, and their basic regulation and structure).
Knowledge about the basic processes of biological regulation (transcription, translation, etc.).
Knowledge about the chemical and physical bases of life (concept of pH, concentration gradients, etc.).

Objectives

Identify cellular structures, cellular organelles and know their function and biological relevance.
Understand the general intra and extracellular communication processes.
Understand the concept of cell cycle and its regulation.
Understand the fundamentals of cell regulation at the organizational level in organs and tissues, homeostasis, cell renewal and pluri- and multipotency.
Understand the process of gametogenesis, meiosis and fecundation, at the cellular level.
Explain the process of embryo formation and the early stages of human embryonic development at the cellular level.
Understand and assess the applicability of cellular models in biomedicine.

Competences/Learning outcomes of the degree programme

CB01 - Students must demonstrate that they have and understand knowledge in an area of study that is based on general secondary education, and it tends to be found at a level that, although it is based on advanced textbooks, also includes some aspects that involve knowledge from the cutting-edge of their field of study.
CB03 - Students must have the ability to bring together and interpret significant data (normally within their area of study) to issue judgements that include a reflection on significant issues of a social, scientific and ethical nature.
CB04 - That students can transmit information, ideas, problems and solutions to specialist and non-specialist audiences.
CE01 - To have a comprehensive overview of the structure and function of the cell, as well as intra and extracellular communication and its regulation through the main routes of cell signalling, in developing adult individuals.
CG01 - To be aware of basic biological concepts and language specific to biomedical sciences and health status.
CG11 - To be aware of basic concepts from different fields connected to biomedical sciences.
CT01 - To develop the organisational and planning skills that are suitable in each moment.
CT02 - To develop the ability to resolve problems.
CT03 - To develop analytical and summarising skills.
CT04 - To interpret experimental results and identify consistent and inconsistent elements.
CT05 - To use the internet as a means of communication and a source of information.
CT06 - To know how to communicate, give presentations and write up scientific reports.
CT07 - To be capable of working in a team.
CT08 - To reason and evaluate situations and results from a critical and constructive point of view.
CT09 - To have the ability to develop interpersonal skills.
CT10 - To be capable of autonomous learning.
CT11 - To apply theoretical knowledge to practice.
CT12 - To apply scientific method.
CT13 - To be aware of the general and specific aspects related to the field of nutrition and ageing.
CT14 - To respect the fundamental rights of equality between men and women, and the promotion of human rights and the values that are specific to a culture of peace and democratic values.

Learning outcomes of the subject

At the end of the course, the student:

Know the structure and composition of eukaryotic and prokaryotic cells.
Knows the structure and function of animal cells, and acquires an integrated view at the molecular, structural and functional levels of cellular structures.
Understand and properly use scientific terminology and concepts used in the field of cell biology.
Search, organize and effectively communicate scientific information.
Develop a critical spirit.
Train the ability to discuss complex concepts and present hypotheses.

Syllabus

Lecture 1 – Presentation. Introduction to Cell Biology. Scientific method.
Lecture 2 - The cell. Universal features. Prokaryotes and eukaryotes.
Lecture 3 - Case method 1 - Cell evolution. Viruses and extraterrestrial life.
Lecture 4 - Plasma membrane. Membrane lipids and proteins
Lecture 5 - Transmembrane transport. Transporters and channels.
Lecture 6 - Intracellular signalling. Receptors, ligands. Signaling pathways.
Lecture 7 - Case method 2 - Activities on transport and signalling.
Lecture 8 - Endomembranes I. Endoplasmic reticulum.
Lecture 9 - Endomembranes II. Golgi apparatus.
Lecture 10 - Endomembranes III. Vesicular transport. Endo-exocytosis.
Lecture 11 - Case method 3 - Problems about protein trafficking and endomembranes.
Lecture 12 - Nucleus. Membrane and nuclear transport. Nucleolus.
Lecture 13 - Case method 4 - Problems and review.
Lecture 14 - Bioenergetics: mitochondria, peroxisomes.
Lecture 15 - The cell cycle.
Lecture 16 - Case method 5 - Cytoskeleton.
Lecture 17 - Embryonic development I.
Lecture 18 - Case method 6 - Cell junctions.
Lecture 19 - Embryonic development II.
Lecture 20 - Case method 7 - Meiosis. Germ cells and fertilization.
Lecture 21 - Differentiated cells and tissue maintenance.
Lecture 22 - Case method 8 - Cell death. Apoptosis.
Lecture 23 - Cell-based therapies.

Teaching and learning activities

In person

Lecture class
Team work
Individual work
Debate
Public presentation

Evaluation systems and criteria

In person

The total grade of the subject will be calculated as follows:

Students in first call:

20% Midterm exam.
15% Laboratory sessions participation, attitude, and laboratory test.
20% Preparation, participation and attitude in case methods. The score will be the average of each session and/or each submitted work.
45% Final exam.
Up to 0.5 additional points in case of an excellent participation and attitude in magisterial lectures, case methods or lab sessions (contribution of interesting ideas or posing of pertinent questions that help to improve the quality of the session).

Students in second call: will do an exam in July that will count 65% of the final grade and that will average with the grade of laboratory sessions (15%), and preparation of the case methods (20%) obtained in the first call. Midterm exam will not be taken into account (unless the student requests it).

Students with two or more than two deadlines: they will do the final exam of each call that will count 65% of the final grade and that will averaged with the laboratory sesions grade (15%), and preparation of the case methods (20%) obtained in the first announcement. Whenever they wish, the students can repeat the attendance to the laboratory practices and case methods (and/or repeat the midterm exam) to obtain a new grade; in this case, the student must comunicate it to the coordinator in advance.

Important points to keep in mind regarding attendance:

1) Attendance to laboratory practices is mandatory. In case the student cannot attend a given session, a justification must be sent to the course coordinator in advance. Non-justified non-attendance means an automatic failure of the course.

2) Attendance to magistral lectures is not mandatory, but advisable.

3) Atendance to case methods is not mandatory, but higly advisable. In case the student cannot attend a given session, a justification should be sent to the course coordinator in advance. The grade for the case methods will be the average of each of the sessions (assignment, presentation or exam). The non-delivery of any of these activities will result in a zero in the evaluation of that session, which will be averaged with the rest of the sessions.

Important points to keep in mind regarding evaluation:

1) To pass the course, it is necessary to meet these two conditions: a minimum grade of 5.0 must be obtained in the final course grade, and a minimum grade of 5.0 must be obtained in the final exam (first or second call).

2) The exams will be a combination of questions with short written answers, and test type questions (with 4 answer options, the correct anwer counting +1 points, the incorrect answers counting -0.3 point, and the no-answer counting 0 points).

Bibliography and resources

In english:

Alberts B. et al., Essential Cell Biology. Fourth edition (2013), or fifth edition (2018). Garland Science.
Alberts B, et al. Molecular Biology of the Cell. 6th edition. Garland Science, 2015.
Lodish H, et al. Molecular Cell Biology. 7th edition Macmillan Learning, 2013 (8th edition, 2016).

En español:

Alberts B. et al., Introducción a la Biología Celular, 3ª edición, Editorial Médica Panamericana SA, 2011
Alberts, B et al. Biología Molecular de la Célula. 6ª edición. Ediciones Omega 2016.
Lodish et al. Biología Celular y Molecular. 7ª edición. Editorial Médica Panamericana S.A. 2016.

Evaluation period

E: exam date | R: revision date | 1: first session | 2: second session:

E1 15/01/2024 A16 14:00h
R1 23/01/2024 A16 16:00h
E2 17/06/2024 A04 09:00h

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