Statements of Mentorship


History, Teaching, and Public Awareness

Statements of Mentorship
Daniel A. Colón-Ramos1,2,3

https://doi.org/10.1523/ENEURO.0411-18.2018

1Department of Neuroscience, Program in Cellular Neuroscience, Neurodegeneration and Repair, Yale University
School of Medicine, New Haven, CT 06510, 2Department of Cell Biology, Yale University School of Medicine, CT
06510, and 3Instituto de Neurobiología, Recinto de Ciencias Médicas, Universidad de Puerto Rico, San Juan
00926-1117, PR

Key words: Landis Award; mentor; mentoring

The Landis Award for Outstanding Mentorship was cre-
ated in 2018 by the National Institute of Neurological
Disorders and Stroke (NINDS) to recognize that “mentor-
ship and training are critical to the development of excep-
tional future scientists” and to honor the legacy of former
NINDS Director Story Landis, PhD, in mentoring genera-
tions of neuroscientists. I was honored to be nominated
by my mentees and then selected by the committee as
part of the inaugural group that received the award. While
profoundly touched by the recognition, I am the first to
admit that in mentoring, my aspirations exceed my ca-
pacities or training (and anybody who has worked in my
lab will be the second to admit that). My mentorship skills
are a work in progress.

Yet unlike scientific ideas, which are also “works in
progress” that benefit from the critiques of our peers,
mentoring approaches seldom benefit from the com-
ments and wisdom of our colleagues and mentees. For
example, I must have written, in the 10 years I have been
faculty member, dozens of research statements and
plans, progress reports, and grants that have all benefited
from the collective wisdom of my colleagues and men-
tees. My science is better for it. Yet, when it comes to one
of the most important activities I do, the training of men-
tees, it was in preparing for the Landis Award that I wrote
my very first Statement of Mentorship.

To be sure, one could argue that writing a Statement of
Mentorship is not necessary or even important to being a
good mentor. That the tasks necessary for being a good
mentor are self-evident. Some might even argue that the
best way to be a good mentor is to focus solely on the
scientific ideas, not so much on the individual mentee. Yet
I would argue that the few times I have gotten feedback
on my mentoring, I have benefited tremendously from it,
and so have my mentees and the science we do together
(Fig. 1). When it comes to learning, be it in mentoring or
regarding new scientific ideas or techniques, I worry
about the “blind spots,” that which I do not know that I do
not know. The remedy for that, when it comes to scientific
ideas, has been open, effective, and critical discussions
with my peers. Could our mentoring, similar to our scien-
tific ideas, benefit from the collective wisdom and expe-
rience from our colleagues and mentees?

In that spirit, below I share my lab’s Statement of Men-
torship submitted to the Landis Award, not as a finished
set of ideas, but as a living statement of our lab’s aspira-
tions and to initiate a dialogue around mentorship. I also
share a number of mentoring resources who Dr. Michelle
Jones-London from NINDS kindly sent me.

Statement of Mentorship
No matter who we are and no matter where we were

born, we share a fundamental curiosity about the world

Received October 24, 2018; accepted October 26, 2018; First published
November 29, 2018.
Acknowledgements: I thank past and present mentors for serving as role

models and guiding me, through their actions, in this adventure of becoming a
scientist and a mentor. I also want to thank my lab members, past and present,
who taught me, in honest exchanges, to become a better mentor, scientist,
and human being. They also helped polish some of the ideas and interests
presented here through discussions at lab retreats, lab meetings, and by
proofreading the mentoring statement. I want to thank in particular Emily
Wang, Valentina Greco, Antonio Giraldez, Marc Hammarlund, and David Berg
for thoughtful comments on the article, and for many years of discussions on
these topics. I thank the Research Center for Minority Institutions program, the
Instituto de Neurobiología de la Universidad de Puerto Rico, and the Marine
Biological Laboratories for providing a yearly meeting and brainstorming plat-
form for these ideas.

This work is supported by the National Institutes of Health (NIH) Grant
R01NS076558), NIH Pioneer Award, the National Science Foundation Grant
IOS 1353845, and the Howard Hughes Medical Institute Faculty Scholars
program.

Correspondence should be addressed to Dr. Daniel A. Colón-Ramos, De-
partment of Neuroscience and Cell Biology, Yale School of Medicine, 333
Cedar Street, SHM B 163D, New Haven, CT 06510. E-mail: daniel.colon-
ramos@yale.edu.

https://doi.org/10.1523/ENEURO.0411-18.2018
Copyright © 2018 Colón-Ramos
This is an open-access article distributed under the terms of the Creative
Commons Attribution 4.0 International license, which permits unrestricted use,
distribution and reproduction in any medium provided that the original work is
properly attributed.

Commentary

November/December 2018, 5(6) e0411-18.2018 1–4

https://doi.org/10.1523/ENEURO.0411-18.2018
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around us. That shared human instinct does not mean we
are all meant to become scientists, that we all share the
same motivations, or that we think similarly about science
or the world around us. But it does mean that our shared
curiosity is a fundamental aspect of our humanity. This
universality is foundational to my philosophy as a mentor
in science. I therefore start my mentoring pledge with an
aspiration to “do no harm” to my mentee’s innate interest
in science.

While I recognize the universality of scientific curiosity,
I also recognize that individual backgrounds shape our
engagement with science. Our individual experiences dif-
fer based on the intersectionality of our identities, which
includes our identity as scientists but also includes our
race/ethnicity, gender identity, religion, culture, socioeco-
nomic status, etc. These factors influence our interests,
motivations, and scientific ideas. It is in the richness of
this intersectionality that most of the opportunities and
challenges lie for me as a mentor.

Science works best to produce truly novel insights
when influenced by diverse ideas from individuals working
together. I intentionally create a space within my labora-
tory which harnesses our collective interests to build
strong teams joined in a common pursuit of fundamental
discoveries in science, while recognizing and celebrating
our diverse backgrounds and identities. Supporting a di-
verse group of mentees creates both interpersonal and
group dynamics that reflect issues at play in our scientific
communities and, at large, concerns of racial, gender, and

socioeconomic equity, for example. This means opening
a lab meeting with a discussion of the “#metoo” move-
ment in academia; it means postponing afternoon meet-
ings after the death of Eric Garner to talk to a mentee of
color about what this death represents for her, as an
underrepresented scientist of color working at Yale Uni-
versity; it means traveling with my lab to Puerto Rico after
the archipelago was devastated by Hurricane Maria to
support and learn from our colleagues there (Fig. 1). In
other words, recognizing, respecting, and fostering
unique perspectives means challenging normative stan-
dards, not only in the scientific paradigms tackled by our
research program but also in the paradigms of who and
how people are meant to succeed in science. How this
philosophy towards mentorship translates at the bench
includes active listening to arguments, challenging as-
sumptions, and rigorous examination of the foundations
of a discovery, all while respecting the dignity of the
individual and fostering their growth as a scientist. Bal-
ancing rigor while fostering growth requires investing the
time needed to know and appreciate the individual per-
spectives of my mentees.

I have established the following mentoring approach to
achieve this:
1. Common approaches to scientific excellence by

investing in the individual. There are some funda-
mental skills I feel all aspiring scientists need to learn
(and experienced scientists need to polish) when rig-
orously approaching scientific problems. Those skills

Figure 1. Colón-Ramos lab in the Annual Lab Retreat in San Juan, Puerto Rico (March, 2018). In 2018, after Hurricane María, we
decided to conduct our annual lab retreat and workshops in San Juan, PR. From left to right: Ernesto Cabezas-Bou, Mark Moyle,
Leighton Duncan, Agustin Almoril-Porras, Shavani Prashad, Sarah Hill, Sisi Yang, Titas Sengupta, Richard Ikegami, Zhao Xuan, and
Joon Lee. Not in the picture: Mayra Blakey, Josh Hawk, SoRi Jang, Ian Gonzalez, Laura Manning, Milind Singh, Noelle Koonce, and
Lin Shao.

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include recognizing assumptions in experimental de-
sign, achieving best practices of reproducibility in
quantifications and data analyses, and recognizing
biases (among other skills). The way I approach men-
toring and training is through structured meetings
that invest heavily in the individual towards under-
standing their drive, their unique perspectives, and
how each can build towards the development of
these skills. Specifically, upon arriving at the lab,
each mentee is given a binder which includes infor-
mation on the lab’s mission and our mentoring phi-
losophy. We establish weekly meetings to discuss
experimental design, findings, and interpretations.
These meetings are tailored to encourage indepen-
dent critical thinking and project ownership, so men-
tees are asked to think about their experimental
design, results, and interpretations prior to the meet-
ing. Then, during the meetings, we focus on in-depth
discussions in which mentees present their thoughts,
identify and challenge assumptions, and conceptual-
ize their research questions in broader contexts of
overarching significance. Once a year, we have a
dedicated meeting to discuss motivation and career
goals, in which the mentee answers a set of ques-
tions in writing which include self-assessment of
strengths and areas of improvement as a scientist,
evaluation of my performance as a mentor, and their
project and personal career goals. These meetings
provide an opportunity to understand, not only the
strengths of the mentee, but their individual needs
and their intersectionality of identity in the context of
their motivation and progress. The meetings provide
continuous reinforcement of key precepts of the sci-
entific process (identifying assumptions, biases and
good experimental design) while also creating a men-
torship framework in which the mentees progres-
sively grow as independent thinkers and in their
identity as scientists.

2. Model by example: approaching science with
rigor and humility. In science, knowledge is impor-
tant but only as a first step to recognize the bound-
aries of what we know and, importantly, where they
end. It is therefore critical for the training scientist to
feel comfortable in recognizing, with humility, their
ignorance. I model this by making it clear to my
mentees that I do not have all the answers, not in the
research projects they are driving, and not in men-
toring. Like the research projects, I approach men-
toring as a team activity in which the mentor-mentee
pair jointly learns how to navigate the new terrain.
Being comfortable with recognizing our ignorance
does not mean being complacent in mediocrity. The
recognition of ignorance requires rigor and is a first
step towards the recognition of opportunities in
learning and growth. But in that process, while I am
partial and supportive to the mentee, I am impartial
and tough towards the work. I also request, and
welcome, a similar treatment from the mentee to-
wards my own ideas, biases, and assumptions.

3. Creating a network of mentors. Mentoring in my lab
happens during individual sessions and also in sub-
group meetings of teams working in conceptually
related projects. The purpose of these meetings is to
create a network of mutual mentoring and support.
To achieve this, my lab and I have jointly brain-
stormed and designed activities that allow us all to
grow in our roles. We recognize that being mentors or
mentees, like being teachers or students, is rela-
tional, these are not fixed roles, and the roles change
depending on the context. As scientists in the pursuit
of knowledge, we need the mental agility to be both
mentors and mentees. To learn this, all my mentees
also serve as mentors to new lab members, regard-
less of hierarchy in training. Experience is important
for being a good mentor but is not sufficient; being a
good mentor also requires skills in listening and
teaching. To train in mentorship, the lab and I jointly
created a mentoring document in which we articulate
the responsibilities of both mentors and mentees. We
also have sessions to discuss how we can all be
better teachers and students to each other. In that
way, we move beyond the normative hierarchical
structures in scientific training and instead create a
web of mutual accountability and support in which
responsibility and leadership is encouraged. Finally,
the relationship of shared accountability between lab
members is reinforced through an annual two-day lab
retreat in which we discuss in depth and in an infor-
mal but stimulating setting the future of the lab (Fig.
1). In these meetings, we discuss the progression of
projects, overarching conceptual questions of the
field and what our lab can do to address them. The
purpose of the lab retreat is to create a space away
from the demands of everyday bench work to facili-
tate this introspection, evaluation, and discussion.
Discussions in the retreat have also included career
path navigation, science and society conversations
on bioethics and policy, and discussions on scientific
reproducibility and transparency based on the Landis
et al. (2012) report.

In summary, my mentoring philosophy is based on
recognizing, respecting, and investing in the individual,
celebrating diversity of thought, and fostering collabora-
tive efforts that allow us to jointly bring our unique expe-
riences to bear in addressing the cell biology of the
synapse and behavior. I work to create a lab environment
which honors scientific rigor and respects the dignity of
individuals to create a learning and discovery space
where we are all comfortable identifying and recognizing
our unique strengths and opportunities for growth.

This mentoring document was jointly prepared in col-
laboration with lab members who read and edited the
document.

Mentoring resources:
NRMN, CienciaPR.org, or mentor training
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4477740/
Mentoring articles on SfN Neuronline

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https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4477740/


http://neuronline.sfn.org/Career-Specific-Topics/
Professional-Development

How to Get the Mentoring You Want: A Guide for
Graduate Students at a Diverse University

http://www.rackham.umich.edu/downloads/publications/
mentoring.pdf

Making the Right Moves and Training Scientists to
Make the Right Moves

http://www.hhmi.org/programs/resources-early-career-
scientist-development

Individual Development Plan (IDP), a Web-based career-
planning tool created to help graduate students and post-
docs in the sciences define and pursue their career goals

http://myidp.sciencecareers.org/

National Research Mentoring Network
https://nrmnet.net/
Mentoring Compacts:
Example compacts for download are available at
https://ictr.wisc.edu/mentoring/mentoring-compacts

contracts-examples/

Reference
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(2012). A call for transparent reporting to optimize the predictive
value of preclinical research. Nature. 490:187–191. Medline

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http://neuronline.sfn.org/Career-Specific-Topics/Professional-Development
http://neuronline.sfn.org/Career-Specific-Topics/Professional-Development
http://www.rackham.umich.edu/downloads/publications/mentoring.pdf
http://www.rackham.umich.edu/downloads/publications/mentoring.pdf
http://www.hhmi.org/programs/resources-early-career-scientist-development
http://www.hhmi.org/programs/resources-early-career-scientist-development
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https://ictr.wisc.edu/mentoring/mentoring-compactscontracts-examples/
http://www.ncbi.nlm.nih.gov/pubmed/23060188

	Statements of Mentorship
	Statement of Mentorship

	Reference